CD33-related sialic-acid-binding immunoglobulin-like lectins in health and disease

Sialic-acid-binding immunoglobulin-like lectins (Siglecs) are members of the Ig superfamily that bind sialic acids in different linkages in a wide variety of glycoconjugates. These membrane receptors are expressed in a highly specific manner, predominantly within the haematopoietic system. The CD33-related Siglecs represent a distinct subgroup that is undergoing rapid evolution. The structural features of CD33-related Siglecs and the frequent presence of conserved cytoplasmic signalling motifs point to roles in regulating leukocyte functions that are important during inflammatory and immune responses. In this review, we summarise ligand binding preferences and describe recent progress in elucidating the functional roles of CD33-related Siglecs in the immune system. We also discuss the potential for targeting novel therapeutics against these surface receptors.     

Siglec and anti-Siglec therapies

Siglecs (sialic acid–binding immunoglobulin-like lectins) are a family of receptors that bind sialic acids in specific linkages on glycoproteins and glycolipids. Siglecs play roles in immune signalling and exhibit cell-type specific expression and endocytic properties. Recent studies suggest that Siglecs are likely to function as immune checkpoints that regulate responses in cancers and inflammatory diseases. In this review, we discuss strategies to target the Siglec–sialic acid axis in human diseases, particularly cancer, and the possibility of exploiting them for therapeutic intervention.     

Siglecs: sialic-acid-binding immunoglobulin-like lectins in cell-cell interactions and signalling

Siglecs are sialic-acid-binding immunoglobulin-like lectins involved in cell-cell interactions and signalling functions in the haemopoietic, immune and nervous systems. Significant advances have been made in our understanding of the link between carbohydrate recognition and signalling for two well-characterised siglecs, CD22 and myelin-associated glycoprotein. Over the past few years, several novel siglecs have been discovered through genomics and functional screens. These "CD33-related" siglecs have molecular features of inhibitory receptors and may be important in regulating leucocyte activation during immune and inflammatory responses.     

Lectin Galactoside-binding Soluble 3 Binding Protein (LGALS3BP) Is a Tumor-associated Immunomodulatory Ligand for CD33-related Siglecs

Lectin galactoside-binding soluble 3 binding protein (LGALS3BP, also called Mac-2 binding protein) is a heavily glycosylated secreted molecule that has been shown previously to be up-regulated in many cancers and has been implicated in tumor metastatic processes, as well as in other cell adhesion and immune functions. The CD33-related subset of sialic acid-binding immunoglobulin-like lectins (Siglecs) consists of immunomodulatory molecules that have recently been associated with the modulation of immune responses to cancer. Because up-regulation of Siglec ligands in cancer tissue has been observed, the characterization of these cancer-associated ligands that bind to inhibitory CD33-related Siglecs could provide novel targets for cancer immunomodulatory therapy. Here we used affinity chromatography of tumor cell extracts to identify LGALS3BP as a novel sialic acid-dependent ligand for human Siglec-9 and for other immunomodulatory Siglecs, such as Siglec-5 and Siglec-10. In contrast, the mouse homolog Siglec-E binds to murine LGALS3BP with lower affinity. LGALS3BP has been observed to be up-regulated in human colorectal and prostate cancer specimens, particularly in the extracellular matrix. Finally, LGALS3BP was able to inhibit neutrophil activation in a sialic acid- and Siglec-dependent manner. These findings suggest a novel immunoinhibitory function for LGALS3BP that might be important for immune evasion of tumor cells during cancer progression.     

Microglial carbohydrate-binding receptors for neural repair

Microglia are the resident immune cells of the central nervous system (CNS) and perform typical scavenging and innate immune functions. Their capacity to eliminate extracellular aggregates and apoptotic neural material without inflammation is crucial for brain tissue homeostasis and repair. To fulfill these tasks, microglia express a whole set of recognition receptors including toll-like (TLRs), carbohydrate-binding, Fc, complement and cytokine receptors. Receptors recognizing carbohydrate structures are strongly involved in microglial repair function. Carbohydrate-binding receptors can be divided into two major subgroups: the sulfated glycosaminoglycan (SGAG)-binding receptors and the lectins (Siglecs, galectins, selectins). SGAG-binding receptors recognize anionic structural motifs within extended SGAG chains. Siglecs bind to the sialic acid cap of the intact glycocalyx. Other lectin family members such as galectins recognize lactosamine units typically exposed after alteration of the glycocalyx. Dependent on the type of microglial carbohydrate-binding receptors that are stimulated, either a pro-inflammatory cytotoxic or an anti-inflammatory repair-promoting response is evoked. The carbohydrate-binding receptors are also crucial in regulating microglial function such as phagocytosis during neurodegenerative or neuroinflammatory processes. A balance between microglial carbohydrate-binding receptor signaling via an immunoreceptor tyrosine-based activation motif or an immunoreceptor tyrosine-based inhibitory motif is required to polarize microglial cells appropriately so that they create a microenvironment permissive for neural regenerative events.     

A Siglec-like sialic-acid-binding motif revealed in an adenovirus capsid protein

Sialic-acid-binding immunoglobulin-like lectins (Siglecs) are a family of transmembrane receptors that are well documented to play roles in regulation of innate and adaptive immune responses. To see whether the features that define the molecular recognition of sialic acid were found in other sialic-acid-binding proteins, we analyzed 127 structures with bound sialic acids found in the Protein Data Bank database. Of these, the canine adenovirus 2-fiber knob protein showed close local structural relationship to Siglecs despite low sequence similarity. The fiber knob harbors a noncanonical sialic-acid recognition site, which was then explored for detailed specificity using a custom glycan microarray comprising 58 diverse sialosides. It was found that the adenoviral protein preferentially recognizes the epitope Neu5Acα2-3[6S]Galβ1-4GlcNAc, a structure previously identified as the preferred ligand for Siglec-8 in humans and Siglec-F in mice. Comparison of the Siglec and fiber knob sialic-acid-binding sites reveal conserved structural elements that are not clearly identifiable from the primary amino acid sequence, suggesting a Siglec-like sialic-acid-binding motif that comprises the consensus features of these proteins in complex with sialic acid.     

Siglecs--the major subfamily of I-type lectins

Animal glycan-recognizing proteins can be broadly classified into two groups-lectins (which typically contain an evolutionarily conserved carbohydrate-recognition domain [CRD]) and sulfated glycosaminoglycan (SGAG)-binding proteins (which appear to have evolved by convergent evolution). Proteins other than antibodies and T-cell receptors that mediate glycan recognition via immunoglobulin (Ig)-like domains are called "I-type lectins." The major homologous subfamily of I-type lectins with sialic acid (Sia)-binding properties and characteristic amino-terminal structural features are called the "Siglecs" (Sia-recognizing Ig-superfamily lectins). The Siglecs can be divided into two groups: an evolutionarily conserved subgroup (Siglecs-1, -2, and -4) and a CD33/Siglec-3-related subgroup (Siglecs-3 and -5-13 in primates), which appear to be rapidly evolving. This article provides an overview of historical and current information about the Siglecs.     

A second uniquely human mutation affecting sialic acid biology

Siglecs are immunoglobulin superfamily member lectins that selectively recognize different types and linkages of sialic acids, which are major components of cell surface and secreted glycoconjugates. We report here a human Siglec-like molecule (Siglec-L1) that lacks a conserved arginine residue known to be essential for optimal sialic acid recognition by previously known Siglecs. Loss of the arginine from an ancestral molecule was caused by a single nucleotide substitution that occurred after the common ancestor of humans with the great apes but before the origin of modern humans. The chimpanzee Siglec-L1 ortholog remains fully functional and preferentially recognizes N-glycolylneuraminic acid, which is a common sialic acid in great apes and other mammals. Reintroducing the ancestral arginine into the human molecule regenerates the same properties. Thus, the single base pair mutation that replaced the arginine on human Siglec-L1 is likely to be evolutionarily related to the previously reported loss of N-glycolylneuraminic acid expression in the human lineage. Siglec-L1 and its chimpanzee Siglec ortholog also have a different expression pattern from previously reported Siglecs because they are found on the lumenal edge of epithelial cell surfaces. Notably, the human genome contains several Siglec-like pseudogenes that have independent mutations that would have replaced the arginine residue required for optimal sialic acid recognition. Thus, additional changes in the biology of sialic acids may have taken place during human evolution.     

Immunomodulatory activity of extracellular Hsp70 mediated via paired receptors Siglec‐5 and Siglec‐14

The intracellular chaperone heat‐shock protein 70 (Hsp70) can be secreted from cells, but its extracellular role is unclear, as the protein has been reported to both activate and suppress the innate immune response. Potential immunomodulatory receptors on myelomonocytic lineage cells that bind extracellular Hsp70 are not well defined. Siglecs are Ig‐superfamily lectins on mammalian leukocytes that recognize sialic acid‐bearing glycans and thereby modulate immune responses. Siglec‐5 and Siglec‐14, expressed on monocytes and neutrophils, share identical ligand‐binding domains but have opposing signaling functions. Based on phylogenetic analyses of these receptors, we predicted that endogenous sialic acid‐independent ligands should exist. An unbiased screen revealed Hsp70 as a ligand for Siglec‐5 and Siglec‐14. Hsp70 stimulation through Siglec‐5 delivers an anti‐inflammatory signal, while stimulation through Siglec‐14 is pro‐inflammatory. The functional consequences of this interaction are also addressed in relation to a SIGLEC14 polymorphism found in humans. Our results demonstrate that an endogenous non‐sialic acid‐bearing molecule can be either a danger‐associated or self‐associated signal through paired Siglecs, and may explain seemingly contradictory prior reports on extracellular Hsp70 action.     

Role of the cytoskeleton during leukocyte responses

The cytoskeleton is a cellular network of structural, adaptor and signalling molecules that regulates most cellular functions that are related to the immune response, including migration, extravasation, antien recognition, activation and phagocytosis by different subsets of leukocytes. Recently, a large number of regulatory elements and structural constituents of the leukocyte cytoskeleton have been identified. In this review, we discuss the composition and regulation of the different cytoskeletal elements and their role in immune responses.     

Paired Siglec receptors generate opposite inflammatory responses to a human-specific pathogen

Paired immune receptors display near-identical extracellular ligand-binding regions but have intracellular sequences with opposing signaling functions. While inhibitory receptors dampen cellular activation by recognizing self-associated molecules, the functions of activating counterparts are less clear. Here, we studied the inhibitory receptor Siglec-11 that shows uniquely human expression in brain microglia and engages endogenous polysialic acid to suppress inflammation. We demonstrated that the human-specific pathogen Escherichia coli K1 uses its polysialic acid capsule as a molecular mimic to engage Siglec-11 and escape killing. In contrast, engagement of the activating counterpart Siglec-16 increases elimination of bacteria. Since mice do not have paired Siglec receptors, we generated a model by replacing the inhibitory domain of mouse Siglec-E with the activating module of Siglec-16. Siglec-E16 enhanced proinflammatory cytokine expression and bacterial killing in macrophages and boosted protection against intravenous bacterial challenge. These data elucidate uniquely human interactions of a pathogen with Siglecs and support the long-standing hypothesis that activating counterparts of paired immune receptors evolved as a response to pathogen molecular mimicry of host ligands for inhibitory receptors.     

The complex role of B7 molecules in tumor immunology

T-cell activation requires the interaction of the T-cell receptor with a cognate major histocompatibility complex (MHC)-peptide complex. Initiated by antigen engagement, the adaptive immune response is orchestrated by a complex balance between stimulatory and inhibitory signals that are predominantly controlled by members of the B7 family. Here, we review the current knowledge on B7 family members concerning their constitutive and regulated expression, modulation of the immune response and their role in the evasion of host immune surveillance. We also discuss recent therapeutic strategies that aim to improve immune-cell recognition of tumors and induce tolerance to autoreactive immune responses in normal tissues by manipulating B7 functions.     

Inflammasomes in T cells

The concept of non-self recognition through germ-line encoded pattern recognition receptors (PRRs) has been well-established for professional innate immune cells. However, there is growing evidence that also T cells employ PRRs and associated effector functions in response to certain non-self or damage signals. Inflammasomes constitute a special subgroup of PRRs that is hardwired to a signaling cascade that culminates in the activation of caspase-1. Active caspase-1 processes pro-inflammatory cytokines of the IL-1 family and also triggers a lytic programmed cell death pathway known as pyroptosis. An increasing body of literature suggests that inflammasomes are also functional in T cells. On the one hand, conventional inflammasome signaling cascades have been described that operate similarly to pathways characterized in innate immune cells. On the other hand, unconventional functions have been suggested, in which certain inflammasome components play a role in unrelated processes, such as cell fate decisions and functions of T helper cells. In this review, we discuss our current knowledge on inflammasome functions in T cells and the biological implications of these findings for health and disease.     

Siglec-7: a sialic acid-binding lectin of the immunoglobulin superfamily

The Siglecs are a recently discovered family of sialic acid-binding lectins of the immunoglobulin (Ig) superfamily. We report a molecule showing homology to the six first reported Siglecs, with the closest relationship to Siglec-3(CD33), Siglec-5, and Siglec-6(OBBP-1). The extracellular portion has two Ig-like domains, with the amino-terminal V-set Ig domain including amino acid residues known to be involved in sialic acid recognition by other Siglecs. The cytoplasmic domain has putative sites of tyrosine phosphorylation shared with some Siglecs, including an Immuno-receptor Tyrosine-based Inhibitory Motif (ITIM). Expression of the full-length cDNA induces sialic acid-dependent binding to human erythrocytes. A recombinant chimeric form containing the extracellular Ig domains selectively recognizes the sequence Neu5Acalpha2-6Galbeta1-4Glc, and binding requires the side chain of sialic acid. Mutation of an arginine residue predicted to be critical for sialic acid binding abolishes both interactions. Taken together, our findings justify designation of the molecule as Siglec-7. Analysis of bacterial artificial chromosome (BAC) clones spanning the known human genomic location of Siglec-3 indicates that the Siglec-7 gene is also located on chromosome 19q13.3-13.4. Human tissues show strong expression of Siglec-7 mRNA in spleen, peripheral blood leukocytes, and liver. The combination of an extracellular sialic acid binding site and an intracellular ITIM motif suggests that this molecule is involved in trans-membrane regulatory signaling reactions.     

Proximity labeling technologies to illuminate glycan–protein interactions

Glycosylation is a ubiquitous post-translational modification read by glycan-binding proteins (GBP) to encode important functions, but a robust understanding of these interactions and their consequences can be challenging to uncover. Glycan-GBP interactions are transient and weak, making them difficult to capture, and glycosylation is dynamic and heterogenous, necessitating study in native cellular environments to identify endogenous ligands. Proximity labeling, an experimental innovation that labels biomolecules close to a protein of interest, has recently emerged as a powerful strategy to overcome these limitations, allowing interactors to be tagged in cells for subsequent enrichment and identification by mass spectrometry-based proteomics. We will describe this nascent technique and discuss its applications in the last five years with different GBP classes, including Siglecs, galectins, and non-human lectins.     

Cloning, characterization, and phylogenetic analysis of siglec-9, a new member of the CD33-related group of siglecs. Evidence for co-evolution with sialic acid synthesis pathways

The Siglecs are a subfamily of I-type lectins (immunoglobulin superfamily proteins that bind sugars) that specifically recognize sialic acids. We report the cloning and characterization of human Siglec-9. The cDNA encodes a type 1 transmembrane protein with three extracellular immunoglobulin-like domains and a cytosolic tail containing two tyrosines, one within a typical immunoreceptor tyrosine-based inhibitory motif (ITIM). The N-terminal V-set Ig domain has most amino acid residues typical of Siglecs. Siglec-9 is expressed on granulocytes and monocytes. Expression of the full-length cDNA in COS cells induces sialic-acid dependent erythrocyte binding. A recombinant soluble form of the extracellular domain binds to alpha2-3 and alpha2-6-linked sialic acids. Typical of Siglecs, the carboxyl group and side chain of sialic acid are essential for recognition, and mutation of a critical arginine residue in domain 1 abrogates binding. The underlying glycan structure also affects binding, with Galbeta1-4Glc[NAc] being preferred. Siglec-9 shows closest homology to Siglec-7 and both belong to a Siglec-3/CD33-related subset of Siglecs (with Siglecs-5, -6, and -8). The Siglec-9 gene is on chromosome 19q13.3-13.4, in a cluster with all Siglec-3/CD33-related Siglec genes, suggesting their origin by gene duplications. A homology search of the Drosophila melanogaster and Caenorhabditis elegans genomes suggests that Siglec expression may be limited to animals of deuterostome lineage, coincident with the appearance of the genes of the sialic acid biosynthetic pathway.     

New I-type lectins of the CD 33-related siglec subgroup identified through genomics

Siglecs are sialic-acid-binding proteins of the Ig superfamily that are involved in cell-cell interactions and signalling. In recent years, several novel siglecs that are highly related to CD33/Siglec-2 have been identified through genomics and functional screens. In addition to their distinct sialic-acid-binding properties, most of these novel siglecs bear tyrosine-based signalling motifs that are typically found in inhibitory receptors of the immune system. The restricted expression patterns of CD33-related siglecs in the haemopoietic and immune systems suggests that they are involved in regulating leucocyte activation during inflammatory and immune responses.     

Molecular sensors for plant immunity; pattern recognition receptors and race-specific resistance proteins

Plants have to molecularly sense invasions from pathogenic microbes to activate their built-in immune responses. There are two different types of sensor proteins, called immune receptors. They are the indispensible molecular instruments to perceive non-self molecules derived from microbes. A genetic defect of the immune receptors fails to activate immune responses, consequently resulting in disease susceptibility. In general, membrane-bound immune receptors, known to be pattern recognition receptors and exposed on the outside of the cell, recognize microbe-associated molecular patterns from pathogens. Intracellular immune receptors, also called plant disease resistance proteins, directly perceive pathogen-derived effectors or indirectly recognize the effector-mediated modification of host proteins inside the cells. In this review, we introduce the classes and functions of pattern recognition receptors that were molecularly identified so far. Additionally, we summarize recent progresses in structural functions and molecular dynamics of the plant disease resistance proteins.     

无脊椎动物免疫分子多态性

 一般认为,非特异性免疫分子由于胚系基因种类有限而不具备多态性.但近年来人们发现,脊椎动物γ/δ T 细胞受体、B1细胞受体、某些固有免疫成分,以及无脊椎动物的某些免疫球蛋白超家族（immunoglobulin superfamily,IgSF）分子、抗菌肽和模式识别受体（pattern recognition receptors,PRR）等同样具有较高程度的多态性.与特异性免疫分子相似,其多态性形成机制主要为基因组水平的基因重排、单核苷酸多态性、DNA 突变和 mRNA 水平的外显子可变剪接.该多态性的出现可能是无脊椎动物的一种适应性进化,其应为低等生物特异性识别和防御不同病原微生物感染的分子基础. 本文就无脊椎动物免疫分子多态性的最新研究进展及其可能的形成机制与意义进行概述.