Macrophage C-type lectin on bone marrow-derived immature dendritic cells is involved in the internalization of glycosylated antigens

Bone marrow-derived dendritic cells (DCs) were examined for the expression of the murine macrophage C-type lectin specific for galactose and N-acetylgalactosamine (mMGL). Flow cytometric analysis after double staining for MHC class II and mMGL with specific monoclonal antibodies indicated that mMGL was expressed on immature DCs with low to moderate levels of MHC class II and down-regulated during maturation. Immature DCs bound and internalized alpha-N-acetylgalactosaminides conjugated to soluble polyacrylamide (alpha-GalNAc polymers), whereas mature DCs and bone marrow cells did not. The two-color flow cytometric profiles indicated that the degree of alpha-GalNAc polymer bindings exactly coincided with the intensity of the binding of a mMGL-specific monoclonal antibody LOM-14. The internalized alpha-GalNAc polymers seemed to be transported to MHC class II compartments. Thus, mMGL is transiently expressed on bone marrow-derived DCs during their development and maturation and suggested to be involved in the uptake of glycosylated antigens for presentation.     

Mouse Macrophage Galactose-type Lectin (mMGL) is Critical for Host Resistance against Trypanosoma cruzi Infection

The C-type lectin receptor mMGL is expressed exclusively by myeloid antigen presenting cells (APC) such as dendritic cells (DC) and macrophages (Mφ), and it mediates binding to glycoproteins carrying terminal galactose and α- or β-N-acetylgalactosamine (Gal/GalNAc) residues. Trypanosoma cruzi (T. cruzi) expresses large amounts of mucin (TcMUC)-like glycoproteins. Here, we show by lectin-blot that galactose moieties are also expressed on the surface of T. cruzi. Male mMGL knockout (-/-) and wild-type (WT) C57BL/6 mice were infected intraperitoneally with 10⁴ T. cruzi trypomastigotes (Queretaro strain). Following T. cruzi infection, mMGL-/- mice developed higher parasitemia and higher mortality rates compared with WT mice. Although hearts from T. cruzi-infected WT mice presented few amastigote nests, mMGL-/- mice displayed higher numbers of amastigote nests. Compared with WT, Mφ from mMGL-/- mice had low production of nitric oxide (NO), interleukin (IL)-12 and tumor necrosis factor (TNF)-α in response to soluble T. cruzi antigens (TcAg). Interestingly, upon in vitro T. cruzi infection, mMGL-/- Mφ expressed lower levels of MHC-II and TLR-4 and harbored higher numbers of parasites, even when mMGL-/- Mφ were previously primed with IFN-γ or LPS/IFN-γ. These data suggest that mMGL plays an important role during T. cruzi infection, is required for optimal Mφ activation, and may synergize with TLR-4-induced pathways to produce TNF-α, IL-1β and NO during the early phase of infection.     

DC-SIGN; a related gene, DC-SIGNR; and CD23 form a cluster on 19p13

DC-SIGN is a C-type lectin, expressed on a dendritic cell subset. It is able to bind ICAM3 and HIV gp120 in a calcium-dependent manner. Here we report the genomic organization of DC-SIGN and map it to chromosome 19p13 adjacent to the C-type lectin CD23 (FcepsilonRII). We also report a novel, closely linked gene, DC-SIGNR, which shows 73% identity to DC-SIGN at the nucleic acid level and a similar genomic organization. Proteins encoded by both genes have tracts of repeats of 23 aa, predicted to form a coiled coil neck region. They also possess motifs that are known to bind mannose in a calcium-dependent fashion. We show concomitant expression of the two genes in endometrium, placenta, and stimulated KG1 cells (phenotypically similar to monocyte-derived dendritic cells). The existence of a DC-SIGN-related gene calls for reinterpretation of the HIV data to consider possible DC-SIGN/DC-SIGNR hetero-oligomerization.     

Cloning and characterization of the Atlantic salmon serum lectin,a long-form C-type lectin expressed in kidney

We report the cloning of four distinct cDNAs and a genomic sequence encoding a multimeric serum lectin found in the blood of Atlantic salmon (Salmo salar). The sequence variation among the cDNAs as well as genomic Southern blotting analysis revealed a multi-gene family. Expression of the salmon serum lectin (SSL) was specific to kidney, as demonstrated by RT-PCR. Analysis of the 173-amino acid sequence of SSL confirmed that it is a member of the C-type lectin superfamily. Sequence alignments and intron/exon structure of the SSL gene showed it to belong to the type VII C-type lectins, which normally bind to galactose or other ligands, whereas the SSL protein sequence contains the EPN motif of mannose-binding C-type lectins, that bind mannose or related carbohydrates.     

Molecular cloning of a mouse scavenger receptor with C-type lectin (SRCL)(1), a novel member of the scavenger receptor family.

The cDNA clone encoding a mouse scavenger receptor with C-type lectin (SRCL), a novel member of the scavenger receptor family, has been isolated from a mouse embryonic cDNA library. The predicted cDNA sequence contains a 2226 bp open reading frame encoding a coiled-coil, collagen-like, C-type lectin/carbohydrate recognition domain with an overall sequence identity of 92% to human SRCL. In contrast to human, mouse SRCL mRNA was expressed ubiquitously in various adult tissues including the liver and spleen, in which human SRCL mRNA was under detection limits. Mouse SRCL mRNA was expressed in the macrophage cell line J774A.1 cells at a high level and in the embryo as early as E9.     

Cloning and characterization of the Atlantic salmon serum lectin,a long-form C-type lectin expressed in kidney

We report the cloning of four distinct cDNAs and a genomic sequence encoding a multimeric serum lectin found in the blood of Atlantic salmon (Salmo salar). The sequence variation among the cDNAs as well as genomic Southern blotting analysis revealed a multi-gene family. Expression of the salmon serum lectin (SSL) was specific to kidney, as demonstrated by RT-PCR. Analysis of the 173-amino acid sequence of SSL confirmed that it is a member of the C-type lectin superfamily. Sequence alignments and intron/exon structure of the SSL gene showed it to belong to the type VII C-type lectins, which normally bind to galactose or other ligands, whereas the SSL protein sequence contains the EPN motif of mannose-binding C-type lectins, that bind mannose or related carbohydrates.     

Genomic structure, alternative splicing, and physical mapping of the killer cell lectin-like receptor G1 gene (KLRG1), the mouse homologue of MAFA

The mouse killer cell lectin-like receptor G1 (KLRG1), the mouse homologue of the mast cell function-associated antigen (MAFA), is an inhibitory C-type lectin expressed on natural killer (NK) cells and activated CD8 T cells. Here we report the complete nucleotide sequence, alternatively spliced variants, and the physical mapping of the KLRG1 gene in the mouse. The gene spans about 13 kb and consists of five exons. Short interspersed repeats of the B1 and B2 family, a LINE-1-like element, and a (CTT)170 triplet repeat were found in intron sequences. In contrast to human KLRG1 and to the murine KLR family members, mouse KLRG1 locates outside the NK complex on Chromosome 6 between the genes encoding CD9 and CD4.     

Initial steps in lymph node metastasis formation in an experimental system: possible involvement of recognition by macrophage C-type lectins

 We used histological observations and experiments with fluorescent cell tracers to investigate the roles of tissue macrophages in recognition through a galactose/N-acetylgalactosamine-specific C-type lectin (mMGL) in lymph node metastasis formation by mouse ovarian tumor OV2944-HM-1 (HM-1) cells. Lymph node metastasis from subcutaneous sites was shown to be initiated by the entry of tumor cells into the subcapsular sinus of lymph nodes where mMGL-positive cells were mainly located. To investigate whether mMGL-positive cells contributed to host resistance against lymph node metastasis, we repeatedly treated mice bearing transplanted tumors with an mMGL-blocking monoclonal antibody that was known to inhibit mMGL binding to its ligands. The number of HM-1 cells recovered from lymph nodes 2 weeks after subcutaneous injections was significantly greater when the mice were treated with the blocking anti-mMGL antibody. These results suggested that mMGL-positive macrophages contributed to the host's defense against lymph node metastasis. Received: 30 July 1999 / Accepted: 1 November 1999     

Characterization of a novel C-type lectin-like gene, LSECtin: demonstration of carbohydrate binding and expression in sinusoidal endothelial cells of liver and lymph node

A new C-type lectin-like gene encodes 293 amino acids and maps to chromosome 19p13.3 adjacent to the previously described C-type lectin genes, CD23, dendritic cell-specific intercellular adhesion molecule-3-grabbing nonintegrin (DC-SIGN), and DC-SIGN-related protein (DC-SIGNR). The four genes form a tight cluster in an insert size of 105 kb and have analogous genomic structures. The new C-type lectin-like molecule, designated liver and lymph node sinusoidal endothelial cell C-type lectin (LSECtin), is a type II integral membrane protein of approximately 40 kDa in size with a single C-type lectin-like domain at the COOH terminus, closest in homology to DC-SIGNR, DC-SIGN, and CD23. LSECtin mRNA was only expressed in liver and lymph node among 15 human tissues tested, intriguingly neither expressed on hematopoietic cell lines nor on monocyte-derived dendritic cells (DCs). Moreover, LSECtin is expressed predominantly by sinusoidal endothelial cells of human liver and lymph node and co-expressed with DC-SIGNR. LSECtin binds to mannose, GlcNAc, and fucose in a Ca(2+)-dependent manner but not to galactose. Our results indicate that LSECtin is a novel member of a family of proteins comprising CD23, DC-SIGN, and DC-SIGNR and might function in vivo as a lectin receptor.     

Participation of a galactose-specific C-type lectin in Drosophila immunity

A galactose-specific C-type lectin has been purified from a pupal extract of Drosophila melanogaster. This lectin gene, named DL1 (Drosophila lectin 1), is part of a gene cluster with the other two galactose-specific C-type lectin genes, named DL2 (Drosophila lectin 2) and DL3 (Drosophila lectin 3). These three genes are expressed differentially in fruit fly, but show similar haemagglutinating activities. The present study characterized the biochemical and biological properties of the DL1 protein. The recombinant DL1 protein bound to Escherichia coli and Erwinia chrysanthemi, but not to other Gram-negative or any other kinds of microbial strains that have been investigated. In addition, DL1 agglutinated E. coli and markedly intensified the association of a Drosophila haemocytes-derived cell line with E. coli. For in vivo genetic analysis of the lectin genes, we also established a null-mutant Drosophila. The induction of inducible antibacterial peptide genes was not impaired in the DL1 mutant, suggesting that the galactose-specific C-type lectin does not participate in the induction of antibacterial peptides, but possibly participates in the immune response via the haemocyte-mediated mechanism.     

SRCL/CL-P1 recognizes GalNAc and a carcinoma-associated antigen,Tn antigen

SRCL /CL-P1 was recently identified as a scavenger receptor with a C-type lectin domain, which was expressed in vascular endothelial cells and could bind to Gram-positive and Gram-negative bacteria, yeast and oxidized LDL. We found that SRCL was expressed in some but not all nurse-like cells examined. Furthermore, to characterize the C-type lectin domain of SRCL, the secreted form of the C-type lectin domain (LEC-AP) of SRCL, which was fused to the signal sequence of IgG and alkaline phosphatase, was expressed in 293/EBNA-1 cells and the culture medium was used for the in vitro binding assay. LEC-AP specifically bound to GalNAc-conjugated gel in a Ca(2+)-dependent manner, and this binding was inhibited by free GalNAc, L-, D-fucose, D-galactose, lactose, and especially T antigen and Tn antigen. Furthermore, we examined whether or not SRCL could take up saccharide-conjugated particles. 293/EBNA-1 cells stably expressing SRCL were found to take up GalNAc but not mannose-conjugated particles on confocal microscopy. The binding of GalNAc-conjugated particles to these cells was quantitatively measured by comparing the x-means of individual cell populations. An approximately 2.1-fold increase in immunofluorescence intensity was observed for the SRCL transfectants compared to control vector transfectants. Our results provide a basis for understanding the scavenger function of SRCL as to carbohydrate-containing ligands.     

Dendritic cell-associated lectin-1: a novel dendritic cell-associated,C-type lectin-like molecule enhances T cell secretion of IL-4

We have characterized dendritic cell (DC)-associated lectin-1 (DCAL-1), a novel, type II, transmembrane, C-type lectin-like protein. DCAL-1 has restricted expression in hemopoietic cells, in particular, DCs and B cells, but T cells and monocytes do not express it. The DCAL-1 locus is within a cluster of C-type lectin-like loci on human chromosome 12p12-13 just 3' to the CD69 locus. The consensus sequence of the DCAL-1 gene was confirmed by RACE-PCR; however, based on sequence alignment with genomic DNA and with various human expressed sequence tags, we predict that DCAL-1 has two splice variants. C-type lectins share a common sequence motif of 14 invariable and 18 highly conserved aa residues known as the carbohydrate recognition domain. DCAL-1, however, is missing three of the cysteine residues required to form the standard carbohydrate recognition domain. DCAL-1 mRNA and protein expression are increased upon the differentiation of monocytes to CD1a(+) DCs. B cells also express high levels of DCAL-1 on their cell surface. Using a DCAL-1 fusion protein we identified a population of CD4(+) CD45RA(+) T cells that express DCAL-1 ligand. Coincubation with soluble DCAL-1 enhanced the proliferation of CD4(+) T cells in response to CD3 ligation and significantly increased IL-4 secretion. In contrast, coincubation with soluble DC-specific ICAM-3-grabbing nonintegrin (CD209) fusion protein as a control had no effect on CD4(+) T cell proliferation or IL-4 and IFN-gamma secretion. Therefore, the function of DCAL-1 on DCs and B cells may act as a T cell costimulatory molecule, which skews CD4(+) T cells toward a Th2 response by enhancing their secretion of IL-4.     

Identification of a chicken CLEC-2 homologue, an activating C-type lectin expressed by thrombocytes

Receptors on natural killer (NK) cells are classified as C-type lectins or as Ig-like molecules, and many of them are encoded by two genomic clusters designated natural killer gene complex (NKC) and leukocyte receptor complex, respectively. Here, we describe the analysis of an NKC-encoded chicken C-type lectin, previously annotated as homologue to CD94 and NKG2 and thus designated chicken CD94/NKG2. To further elucidate its potential function on NK cells, we produced a specific mab by immunizing with stably transfected HEK293 cells expressing this lectin. Staining of various chicken tissues revealed minimal reactivity with bursal, or thymus cells. In peripheral blood mononuclear cell and spleen, however, the mab reacted with virtually all thrombocytes, whereas most NK cells in organs such as embryonic spleen, lung and intestine were found to be negative. These findings indicate that the gene may not resemble CD94/NKG2, but rather a CLEC-2 homologue, a claim further supported by sequence features such as an additional extracellular cysteine residue and the presence of a cytoplasmic motif known as a hem immunoreceptor tyrosine-based activation motif, found in C-type lectins such as Dectin-1, CLEC-2, but not CD94/NKG2. The biochemical analyses demonstrated that CLEC-2 is present on the cell surface as heavily glycosylated homodimer, which upon mab crosslinking induced thrombocyte activation, as measured by CD107 expression. These analyses reveal that the chicken NKC may not encode NK cell receptor genes, in particular not CD94 or NKG2 genes, and identifies a chicken CLEC-2 homologue.     

Identification, mapping, and genomic structural analysis of an immunoreceptor tyrosine-based inhibition motif-bearing C-type lectin from homozygous clones of rainbow trout (Oncorhynchus mykiss)

Utilizing a spleen-derived cDNA library and rapid amplification of cDNA 5' ends, we cloned a novel type II C-type lectin from two homozygous clones of rainbow trout. The cDNA is 2535 bp in length, and contains a 1017-bp open reading frame. From this sequence, a protein containing 339 amino acids (aa) was deduced. Using PSI-BLAST to search the GenBank database, the deduced protein is a C-type lectin, belonging to the type II membrane receptors. The protein contains four domains: an 87-aa N-terminal cytoplasmic domain, a 21-aa transmembrane domain, an 82-aa neck domain, and a 149-aa C-terminal C-type lectin domain. Two immunoreceptor tyrosine-based inhibition motifs (ITIMs) were located in the N-terminal cytoplasmic domain. RT-PCR results indicated that this gene is transcribed mainly in peripheral blood lymphocytes, spleen, kidney, and gill, and its expression in liver and intestine is weak. Monoclonal antibody 1.14 was used to isolate B cells from peripheral blood lymphocytes. Analysis revealed that this gene is highly expressed in B cells. Genomic DNA was amplified with long-template PCR and sequenced. The gDNA is 12.0 kb in length and contains nine exons and eight introns. The first intron of the genes from the OSU and AR clones differed in length. Based on this difference, the genotype of 69 doubled-haploid offspring of OSU and AR were screened. Subsequently, this gene was mapped on the rainbow trout linkage map to group XXI. Results of a Southern blot indicated that the gene ( TCL-2) exists as a single copy in the rainbow trout genome. The genomic structure, the deduced protein structure, the tissue expression pattern, as well as the phylogenetic analysis of the carbohydrate recognition domain based on the deduced amino acid sequence indicate that TCL-2 resembles CD72; however, the carbohydrate recognition domain sequences of TCL-2 and CD72 are highly diverged.     

The polycystin-1 C-type lectin domain binds carbohydrate in a calcium-dependent manner, and interacts with extracellular matrix proteins in vitro

Mutations in the PKD1 gene are responsible for 85% of cases of autosomal dominant polycystic kidney disease (ADPKD). This gene encodes a large membrane associated glycoprotein, polycystin-1, which is predicted to contain a number of extracellular protein motifs, including a C-type lectin domain between amino acids 403--532. We have cloned and expressed the PKD1 C-type lectin domain, and have demonstrated that it binds carbohydrate matrices in vitro, and that Ca(2+) is required for this interaction. This domain also binds to collagens type I, II and IV in vitro. This binding is greatly enhanced in the presence of Ca(2+) and can be inhibited by soluble carbohydrates such as 2-deoxyglucose and dextran. These results suggest that polycystin-1 may be involved in protein-carbohydrate interactions in vivo. The data presented indicate that there may a direct interaction between the PKD1 gene product and an ubiquitous extracellular matrix (ECM) protein.     

The novel endocytic and phagocytic C-Type lectin receptor DCL-1/CD302 on macrophages is colocalized with F-actin, suggesting a role in cell adhesion and migration

C-type lectin receptors play important roles in mononuclear phagocytes, which link innate and adaptive immunity. In this study we describe characterization of the novel type I transmembrane C-type lectin DCL-1/CD302 at the molecular and cellular levels. DCL-1 protein was highly conserved among the human, mouse, and rat orthologs. The human DCL-1 (hDCl-1) gene, composed of six exons, was located in a cluster of type I transmembrane C-type lectin genes on chromosomal band 2q24. Multiple tissue expression array, RT-PCR, and FACS analysis using new anti-hDCL-1 mAbs established that DCL-1 expression in leukocytes was restricted to monocytes, macrophages, granulocytes, and dendritic cells, although DCL-1 mRNA was present in many tissues. Stable hDCL-1 Chinese hamster ovary cell transfectants endocytosed FITC-conjugated anti-hDCL-1 mAb rapidly (t(1/2) = 20 min) and phagocytosed anti-hDCL-1 mAb-coated microbeads, indicating that DCL-1 may act as an Ag uptake receptor. However, anti-DCL-1 mAb-coated microbead binding and subsequent phagocytic uptake by macrophages was approximately 8-fold less efficient than that of anti-macrophage mannose receptor (MMR/CD206) or anti-DEC-205/CD205 mAb-coated microbeads. Confocal studies showed that DCL-1 colocalized with F-actin in filopodia, lamellipodia, and podosomes in macrophages and that this was unaffected by cytochalasin D, whereas the MMR/CD206 and DEC-205/CD205 did not colocalize with F-actin. Furthermore, when transiently expressed in COS-1 cells, DCL-1-EGFP colocalized with F-actin at the cellular cortex and microvilli. These data suggest that hDCL-1 is an unconventional lectin receptor that plays roles not only in endocytosis/phagocytosis but also in cell adhesion and migration and thus may become a target for therapeutic manipulation.     

Molecular cloning,expression pattern and chromosomal mapping of pig CD69

CD69 is a type II membrane protein belonging to C-type lectin family receptor, and expressed on activated leukocytes. Pig CD69 was cloned by RT-PCR using degenerate primers. Pig CD69 cDNA contains a 600 bp open reading frame with its predicted polypeptide sequence of 200 amino acids. Pig CD69 has 75%, 67%, and 57% sequence identity with cow, human, and mouse CD69, respectively. A splicing isoform, which lacks exon 2 encoding the transmembrane domain, was detected. Pig CD69 gene is located on Chromosome (Chr) 5q25 where the NKG2D gene was mapped. In RT-PCR analysis, pig CD69 mRNA was detected in activated PBL, NK cells, macrophages, monocytes, and granulocytes, but not in resting cells. The inducers for CD69 gene expression were PMA, PHA, LPS, G7 mAb, PNK-E mAb, PM16-6 mAb and the K562 cell line. Moreover, CD69 mRNA is expressed in bone marrow, spleen, thymus and lymph nodes but not in muscle, mammary gland, or the pig kidney cell line (LLC-PK(1)). These results indicate that pig Chr 5q25 contains the NK gene complex and CD69 can be used as an activation marker in pig cells of innate as well as acquired immune systems.     

Cloning, mapping and genomic organization of a fish C-type lectin gene from homozygous clones of rainbow trout (Oncorhynchus mykiss)

Utilizing a splenic cDNA library and rapid amplification of cDNA 5' ends (5'-RACE), a C-type lectin gene was cloned from a homozygous cloned rainbow trout. The 1176 bp cDNA contains a 714 bp open reading frame from which a 238-amino-acid (aa) (27 kDa) protein was deduced. It was confirmed that this protein belongs to the C-type animal lectins, and is a type II membrane receptor. The predicted protein from this sequence contains a 48 aa cytoplasmic domain, a 20 aa transmembrane domain (TM), a 46 aa stalk region and a 124 aa carbohydrate-recognition domain (CRD). The stalk region contains a leucine-zipper, and an N-glycosylation site was also found in the CRD. Sequence alignment and phylogenetic analysis of the CRD indicate that the protein has similarity with human dendritic cell immunoreceptor (DCIR), gp120 binding C-type lectin (gp120BCL) and mammalian hepatic lectins. The N-terminus (aa 4-183) has similarity with NKG2, a group of C-type lectin receptors important in human natural killer cell function. The genomic DNA (gDNA) containing this gene was amplified and sequenced. The 4569 bp gDNA contains five exons and four introns. The first three exons encode the cytoplasmic domain, the TM and stalk region, respectively. Unlike the other type II C-type lectin receptors in which the CRD was encoded by three exons, the CRD of this lectin was encoded by two exons. A transposon Tc1-like fragment was found in intron III. Intron IV is composed of a simple repeat. Tissue-specific expression of the gene was studied by RT-PCR, and it was mainly expressed in spleen and peripheral blood leukocyte (PBL). Using AluI to digest the fragment containing exon I, intron I and exon II, an RFLP was produced between the sequences of this gene in two cloned fish, OSU 142 and Arlee (AR). Seventy-one doubled haploids (DH) of OSU X AR were screened, and the gene was mapped to linkage group XIV on the published map (Young et al., Genetics 148 (1998) 839).