Requirements of peptidoglycan structure that allow detection by the Drosophila Toll pathway

The Drosophila immune system is able to discriminate between classes of bacteria. Detection of Gram-positive bacteria involves a complex of two pattern recognition receptors: peptidoglycan recognition protein SA (PGRP-SA) and Gram-negative binding protein 1 (GNBP1). These activate the Toll signalling pathway. To define the cell wall components sensed by the host, we used highly purified peptidoglycan fragments of two principal Gram-positive bacterial pathogens Staphylococcus aureus and Streptococcus pneumoniae. We report that in both peptidoglycans, the minimal structure needed to activate the Toll pathway is a muropeptide dimer and that the free reducing end of the N-acetyl muramic acid residues of the muropeptides is essential for activity. Monomeric muropeptides were inactive and inhibitory in combination with dimers. Finally, peptidoglycan was degraded by the haemolymph of wild-type but not GNBP1 mutant flies. We suggest a model whereby GNBP1 is involved in the hydrolysis of Gram-positive peptidoglycan producing new glycan reducing ends, which are subsequently detected by PGRP-SA.     

In vivo RNA interference analysis reveals an unexpected role for GNBP1 in the defense against Gram-positive bacterial infection in Drosophila adults

The Drosophila immune system discriminates between different classes of infectious microbes and responds with pathogen-specific defense reactions via the selective activation of the Toll and the immune deficiency (Imd) signaling pathways. The Toll pathway mediates most defenses against Gram-positive bacteria and fungi, whereas the Imd pathway is required to resist Gram-negative bacterial infection. Microbial recognition is achieved through peptidoglycan recognition proteins (PGRPs); Gram-positive bacteria activate the Toll pathway through a circulating PGRP (PGRP-SA), and Gram-negative bacteria activate the Imd pathway via PGRP-LC, a putative transmembrane receptor, and PGRP-LE. Gram-negative binding proteins (GNBPs) were originally identified in Bombyx mori for their capacity to bind various microbial compounds. Three GNBPs and two related proteins are encoded in the Drosophila genome, but their function is not known. Using inducible expression of GNBP1 double-stranded RNA, we now demonstrate that GNBP1 is required for Toll activation in response to Gram-positive bacterial infection; GNBP1 double-stranded RNA expression renders flies susceptible to Gram-positive bacterial infection and reduces the induction of the antifungal peptide encoding gene Drosomycin after infection by Gram-positive bacteria but not after fungal infection. This phenotype induced by GNBP1 inactivation is identical to a loss-of-function mutation in PGRP-SA, and our genetic studies suggest that GNBP1 acts upstream of the Toll ligand Sp?tzle. Altogether, our results demonstrate that the detection of Gram-positive bacteria in Drosophila requires two putative pattern recognition receptors, PGRP-SA and GNBP1.     

A Drosophila pattern recognition receptor contains a peptidoglycan docking groove and unusual L,D-carboxypeptidase activity

The Drosophila peptidoglycan recognition protein SA (PGRP-SA) is critically involved in sensing bacterial infection and activating the Toll signaling pathway, which induces the expression of specific antimicrobial peptide genes. We have determined the crystal structure of PGRP-SA to 2.2-A resolution and analyzed its peptidoglycan (PG) recognition and signaling activities. We found an extended surface groove in the structure of PGRP-SA, lined with residues that are highly diverse among different PGRPs. Mutational analysis identified it as a PG docking groove required for Toll signaling and showed that residue Ser158 is essential for both PG binding and Toll activation. Contrary to the general belief that PGRP-SA has lost enzyme function and serves primarily for PG sensing, we found that it possesses an intrinsic L,D-carboxypeptidase activity for diaminopimelic acid-type tetrapeptide PG fragments but not lysine-type PG fragments, and that Ser158 and His42 may participate in the hydrolytic activity. As L,D-configured peptide bonds exist only in prokaryotes, this work reveals a rare enzymatic activity in a eukaryotic protein known for sensing bacteria and provides a possible explanation of how PGRP-SA mediates Toll activation specifically in response to lysine-type PG.     

A Drosophila Pattern Recognition Receptor Contains a Peptidoglycan Docking Groove and Unusual L,D-Carboxypeptidase Activity

The Drosophila peptidoglycan recognition protein SA (PGRP-SA) is critically involved in sensing bacterial infection and activating the Toll signaling pathway, which induces the expression of specific antimicrobial peptide genes. We have determined the crystal structure of PGRP-SA to 2.2-Å resolution and analyzed its peptidoglycan (PG) recognition and signaling activities. We found an extended surface groove in the structure of PGRP-SA, lined with residues that are highly diverse among different PGRPs. Mutational analysis identified it as a PG docking groove required for Toll signaling and showed that residue Ser158 is essential for both PG binding and Toll activation. Contrary to the general belief that PGRP-SA has lost enzyme function and serves primarily for PG sensing, we found that it possesses an intrinsic L,D-carboxypeptidase activity for diaminopimelic acid-type tetrapeptide PG fragments but not lysine-type PG fragments, and that Ser158 and His42 may participate in the hydrolytic activity. As L,D-configured peptide bonds exist only in prokaryotes, this work reveals a rare enzymatic activity in a eukaryotic protein known for sensing bacteria and provides a possible explanation of how PGRP-SA mediates Toll activation specifically in response to lysine-type PG.     

Dual detection of fungal infections in Drosophila via recognition of glucans and sensing of virulence factors

The Drosophila immune system discriminates between various types of infections and activates appropriate signal transduction pathways to combat the invading microorganisms. The Toll pathway is required for the host response against fungal and most Gram-positive bacterial infections. The sensing of Gram-positive bacteria is mediated by the pattern recognition receptors PGRP-SA and GNBP1 that cooperate to detect the presence of infections in the host. Here, we report that GNBP3 is a pattern recognition receptor that is required for the detection of fungal cell wall components. Strikingly, we find that there is a second, parallel pathway acting jointly with GNBP3. The Drosophila Persephone protease activates the Toll pathway when proteolytically matured by the secreted fungal virulence factor PR1. Thus, the detection of fungal infections in Drosophila relies both on the recognition of invariant microbial patterns and on monitoring the effects of virulence factors on the host.     

Messenger functions of the bacterial cell wall-derived muropeptides

Bacterial muropeptides are soluble peptidoglycan structures central to recycling of the bacterial cell wall and messengers in diverse cell signaling events. Bacteria sense muropeptides as signals that antibiotics targeting cell-wall biosynthesis are present, and eukaryotes detect muropeptides during the innate immune response to bacterial infection. This review summarizes the roles of bacterial muropeptides as messengers, with a special emphasis on bacterial muropeptide structures and the relationship of structure to the biochemical events that the muropeptides elicit. Muropeptide sensing and recycling in both Gram-positive and Gram-negative bacteria are discussed, followed by muropeptide sensing by eukaryotes as a crucial event in the innate immune response of insects (via peptidoglycan-recognition proteins) and mammals (through Nod-like receptors) to bacterial invasion.     

Peptidoglycan molecular requirements allowing detection by the Drosophila immune deficiency pathway

Innate immune recognition of microbes is a complex process that can be influenced by both the host and the microbe. Drosophila uses two distinct immune signaling pathways, the Toll and immune deficiency (Imd) pathways, to respond to different classes of microbes. The Toll pathway is predominantly activated by Gram-positive bacteria and fungi, while the Imd pathway is primarily activated by Gram-negative bacteria. Recent work has suggested that this differential activation is achieved through peptidoglycan recognition protein (PGRP)-mediated recognition of specific forms of peptidoglycan (PG). In this study, we have further analyzed the specific PG molecular requirements for Imd activation through the pattern recognition receptor PGRP-LC in both cultured cell line and in flies. We found that two signatures of Gram-negative PG, the presence of diaminopimelic acid in the peptide bridge and a 1,6-anhydro form of N-acetylmuramic acid in the glycan chain, allow discrimination between Gram-negative and Gram-positive bacteria. Our results also point to a role for PG oligomerization in Imd activation, and we demonstrate that elements of both the sugar backbone and the peptide bridge of PG are required for optimum recognition. Altogether, these results indicate multiple requirements for efficient PG-mediated activation of the Imd pathway and demonstrate that PG is a complex immune elicitor.     

Peptidoglycan molecular requirements allowing detection by Nod1 and Nod2

Nod1 and Nod2 are mammalian proteins implicated in the intracellular detection of pathogen-associated molecular patterns. Recently, naturally occurring peptidoglycan (PG) fragments were identified as the microbial motifs sensed by Nod1 and Nod2. Whereas Nod2 detects GlcNAc-MurNAc dipeptide (GM-Di), Nod1 senses a unique diaminopimelate-containing GlcNAc-MurNAc tripeptide muropeptide (GM-TriDAP) found mostly in Gram-negative bacterial PGs. Because Nod1 and Nod2 detect similar yet distinct muropeptides, we further analyzed the molecular sensing specificity of Nod1 and Nod2 toward PG fragments. Using a wide array of natural or modified muramyl peptides, we show here that Nod1 and Nod2 have evolved divergent strategies to achieve PG sensing. By defining the PG structural requirements for Nod1 and Nod2 sensing, this study reveals how PG processing and modifications, either by host or bacterial enzymes, may affect innate immune responses.     

Drosophila immunity: a large-scale in vivo RNAi screen identifies five serine proteases required for Toll activation

Unlike mammalian Toll-like Receptors, the Drosophila Toll receptor does not interact directly with microbial determinants but is rather activated upon binding a cleaved form of the cytokine-like molecule Spatzle (Spz). During the immune response, Spz is thought to be processed by secreted serine proteases (SPs) present in the hemolymph that are activated by the recognition of gram-positive bacteria or fungi . In the present study, we have used an in vivo RNAi strategy to inactivate 75 distinct Drosophila SP genes. We then screened this collection for SPs regulating the activation of the Toll pathway by gram-positive bacteria. Here, we report the identification of five novel SPs that function in an extracellular pathway linking the recognition proteins GNBP1 and PGRP-SA to Spz. Interestingly, four of these genes are also required for Toll activation by fungi, while one is specifically associated with signaling in response to gram-positive bacterial infections. These results demonstrate the existence of a common cascade of SPs upstream of Spz, integrating signals sent by various secreted recognition molecules via more specialized SPs.     

Expression analysis of proteins encoded by genes of the tag7/tagL (PGRP-S,L) family in human peripheral blood cells

Various types of human blood cells were tested for expression of the Tag7/PGRP-SA and TagL/PGRP-L proteins, which belong to the family of proteins possessing the lysozyme-like peptidoglycan recognition protein (PGRP) domain. Expression regulation by several factors was demonstrated.     

LysM, a widely distributed protein motif for binding to (peptido)glycans

Bacteria retain certain proteins at their cell envelopes by attaching them in a non-covalent manner to peptidoglycan, using specific protein domains, such as the prominent LysM (Lysin Motif) domain. More than 4000 (Pfam PF01476) proteins of both prokaryotes and eukaryotes have been found to contain one or more Lysin Motifs. Notably, this collection contains not only truly secreted proteins, but also (outer-)membrane proteins, lipoproteins or proteins bound to the cell wall in a (non-)covalent manner. The motif typically ranges in length from 44 to 65 amino acid residues and binds to various types of peptidoglycan and chitin, most likely recognizing the N-acetylglucosamine moiety. Most bacterial LysM-containing proteins are peptidoglycan hydrolases with various cleavage specificities. Binding of certain LysM proteins to cells of Gram-positive bacteria has been shown to occur at specific sites, as binding elsewhere is hindered by the presence of other cell wall components such as lipoteichoic acids. Interestingly, LysM domains of certain plant kinases enable the plant to recognize its symbiotic bacteria or sense and induce resistance against fungi. This interaction is triggered by chitin-like compounds that are secreted by the symbiotic bacteria or released from fungi, demonstrating an important sensing function of LysMs.     

Expression Analysis of Proteins Encoded by Genes of the tag7/tagL (PGRP-S, L) Family in Human Peripheral Blood Cells

Various types of human blood cells were tested for expression of the Tag7/PGRP-SA and TagL/PGRP-L proteins, which belong to the family of proteins possessing the lysozyme-like peptidoglycan recognition protein (PGRP) domain. Expression regulation by several factors was demonstrated.     

Rudra interrupts receptor signaling complexes to negatively regulate the IMD pathway

Insects rely primarily on innate immune responses to fight pathogens. In Drosophila, antimicrobial peptides are key contributors to host defense. Antimicrobial peptide gene expression is regulated by the IMD and Toll pathways. Bacterial peptidoglycans trigger these pathways, through recognition by peptidoglycan recognition proteins (PGRPs). DAP-type peptidoglycan triggers the IMD pathway via PGRP-LC and PGRP-LE, while lysine-type peptidoglycan is an agonist for the Toll pathway through PGRP-SA and PGRP-SD. Recent work has shown that the intensity and duration of the immune responses initiating with these receptors is tightly regulated at multiple levels, by a series of negative regulators. Through two-hybrid screening with PGRP-LC, we identified Rudra, a new regulator of the IMD pathway, and demonstrate that it is a critical feedback inhibitor of peptidoglycan receptor signaling. Following stimulation of the IMD pathway, rudra expression was rapidly induced. In cells, RNAi targeting of rudra caused a marked up-regulation of antimicrobial peptide gene expression. rudra mutant flies also hyper-activated antimicrobial peptide genes and were more resistant to infection with the insect pathogen Erwinia carotovora carotovora. Molecularly, Rudra was found to bind and interfere with both PGRP-LC and PGRP-LE, disrupting their signaling complex. These results show that Rudra is a critical component in a negative feedback loop, whereby immune-induced gene expression rapidly produces a potent inhibitor that binds and inhibits pattern recognition receptors.     

Staphylococcus aureus Survives with a Minimal Peptidoglycan Synthesis Machine but Sacrifices Virulence and Antibiotic Resistance

Many important cellular processes are performed by molecular machines, composed of multiple proteins that physically interact to execute biological functions. An example is the bacterial peptidoglycan (PG) synthesis machine, responsible for the synthesis of the main component of the cell wall and the target of many contemporary antibiotics. One approach for the identification of essential components of a cellular machine involves the determination of its minimal protein composition. Staphylococcus aureus is a Gram-positive pathogen, renowned for its resistance to many commonly used antibiotics and prevalence in hospitals. Its genome encodes a low number of proteins with PG synthesis activity (9 proteins), when compared to other model organisms, and is therefore a good model for the study of a minimal PG synthesis machine. We deleted seven of the nine genes encoding PG synthesis enzymes from the S. aureus genome without affecting normal growth or cell morphology, generating a strain capable of PG biosynthesis catalyzed only by two penicillin-binding proteins, PBP1 and the bi-functional PBP2. However, multiple PBPs are important in clinically relevant environments, as bacteria with a minimal PG synthesis machinery became highly susceptible to cell wall-targeting antibiotics, host lytic enzymes and displayed impaired virulence in a Drosophila infection model which is dependent on the presence of specific peptidoglycan receptor proteins, namely PGRP-SA. The fact that S. aureus can grow and divide with only two active PG synthesizing enzymes shows that most of these enzymes are redundant in vitro and identifies the minimal PG synthesis machinery of S. aureus. However a complex molecular machine is important in environments other than in vitro growth as the expendable PG synthesis enzymes play an important role in the pathogenicity and antibiotic resistance of S. aureus.     

Elucidation of the molecular recognition of bacterial cell wall by modular pneumococcal phage endolysin CPL-1

Pneumococcal bacteriophage-encoded lysins are modular proteins that have been shown to act as enzymatic antimicrobial agents (enzybiotics) in treatment of streptococcal infections. The first x-ray crystal structures of the Cpl-1 lysin, encoded by the pneumococcal phage Cp-1, in complex with three bacterial cell wall peptidoglycan (PG) analogues are reported herein. The Cpl-1 structure is folded in two well defined modules, one responsible for anchoring to the pneumococcal cell wall and the other, a catalytic module, that hydrolyzes the PG. Conformational rearrangement of Tyr-127 is a critical event in molecular recognition of a stretch of five saccharide rings of the polymeric peptidoglycan (cell wall). The PG is bound at a stretch of the surface that is defined as the peptidoglycan-binding sites 1 and 2, the juncture of which catalysis takes place. The peptidoglycan-binding site 1 binds to a stretch of three saccharides of the peptidoglycan in a conformation essentially identical to that of the peptidoglycan in solution. In contrast, binding of two peptidoglycan saccharides at the peptidoglycan-binding site 2 introduces a kink into the solution structure of the peptidoglycan, en route to catalytic turnover. These findings provide the first structural evidence on recognition of the peptidoglycan and shed light on the discrete events of cell wall degradation by Cpl-1.     

Cell wall component and mycotoxin moieties involved in the binding of fumonisin B1 and B2 by lactic acid bacteria

Aims:  The ability of lactic acid bacteria (LAB) to bind fumonisins B₁ and B₂ (FB₁, FB₂) in fermented foods and feeds and in the gastrointestinal tract could contribute to decrease their bioavailability and toxic effects on farm animals and humans. The aim of this work was to identify the bacterial cell wall component(s) and the functional group(s) of FB involved in the LAB–FB interaction.
Methods and Results:  The effect of physicochemical, enzymatic and genetic treatments of bacteria and the removal/inactivation of the functional groups of FB on toxin binding were evaluated. Treatments affecting the bacterial wall polysaccharides, lipids and proteins increased binding, while those degrading peptidoglycan (PG) partially decreased it. In addition, purified PG from Gram-positive bacteria bound FB in a manner analogue to that of intact LAB. For FB, tricarballylic acid (TCA) chains play a significant role in binding as hydrolysed FB had less affinity for LAB.
Conclusions:  Peptidoglycan and TCA are important components of LAB and FB, respectively, involved in the binding interaction.
Significance and Impact of the Study:  Lactic acid bacteria binding efficiency seems related to the peptide moiety structure of the PG. This information can be used to select probiotics with increased FB binding efficiency.     

Toll-like receptor 2-dependent bacterial sensing does not occur via peptidoglycan recognition

Toll-like receptor 2 (TLR2) has been shown to recognize several classes of pathogen-associated molecular patterns including peptidoglycan (PG). However, studies linking PG with TLR2 recognition have relied mainly on the use of commercial Staphylococcus aureus PG and have not addressed TLR2 recognition of other PG types. Using highly purified PGs from eight bacteria (Escherichia coli, Pseudomonas aeruginosa, Yersinia pseudotuberculosis, Helicobacter pylori, Bacillus subtilis, Listeria monocytogenes, Streptococcus pneumoniae and S. aureus), we show that these PGs are not sensed through TLR2, TLR2/1 or TLR2/6. PG sensing is lost after removal of lipoproteins or lipoteichoic acids (LTAs) from Gram-negative and Gram-positive cell walls, respectively. Accordingly, purified LTAs are sensed synergistically through TLR2/1. Finally, we show that elicited peritoneal murine macrophages do not produce tumour necrosis factor-alpha or interleukin-6 in response to purified PGs, suggesting that PG detection is more likely to occur intracellularly (through Nod1/Nod2) rather than from the extracellular compartment.     

Crystal structure of human peptidoglycan recognition protein S (PGRP-S) at 1.70 A resolution

Peptidoglycan recognition proteins (PGRPs) are pattern recognition receptors of the innate immune system that bind peptidoglycans (PGNs) of bacterial cell walls. These molecules, which are highly conserved from insects to mammals, contribute to host defense against infections by both Gram-positive and Gram-negative bacteria. Here, we present the crystal structure of human PGRP-S at 1.70A resolution. The overall structure of PGRP-S, which participates in intracellular killing of Gram-positive bacteria, is similar to that of other PGRPs, including Drosophila PGRP-LB and PGRP-SA and human PGRP-Ialpha. However, comparison with these PGRPs reveals important differences in both the PGN-binding site and a groove formed by the PGRP-specific segment on the opposite face of the molecule. This groove, which may constitute a binding site for effector or signaling proteins, is less hydrophobic and deeper in PGRP-S than in PGRP-IalphaC, whose PGRP-specific segments vary considerably in amino acid sequence. By docking a PGN ligand into the PGN-binding cleft of PGRP-S based on the known structure of a PGRP-Ialpha-PGN complex, we identified potential PGN-binding residues in PGRP-S. Differences in PGN-contacting residues and interactions suggest that, although PGRPs may engage PGNs in a similar mode, structural differences exist that likely regulate the affinity and fine specificity of PGN recognition.     

The N-terminal Domain of Drosophila Gram-negative Binding Protein 3 (GNBP3) Defines a Novel Family of Fungal Pattern Recognition Receptors

Gram-negative binding protein 3 (GNBP3), a pattern recognition receptor that circulates in the hemolymph of Drosophila, is responsible for sensing fungal infection and triggering Toll pathway activation. Here, we report that GNBP3 N-terminal domain binds to fungi upon identifying long chains of β-1,3-glucans in the fungal cell wall as a major ligand. Interestingly, this domain fails to interact strongly with short oligosaccharides. The crystal structure of GNBP3-Nter reveals an immunoglobulin-like fold in which the glucan binding site is masked by a loop that is highly conserved among glucan-binding proteins identified in several insect orders. Structure-based mutagenesis experiments reveal an essential role for this occluding loop in discriminating between short and long polysaccharides. The displacement of the occluding loop is necessary for binding and could explain the specificity of the interaction with long chain structured polysaccharides. This represents a novel mechanism for β-glucan recognition.The activation of the immune response is energetically costly and may be detrimental to the host, especially when inappropriately triggered. Therefore, the reliable detection of infections is a step of paramount importance in the immune response. To achieve the task of detecting potentially hazardous microorganisms, the innate immune system relies on several strategies. One of them is to sense both pathogenic and nonpathogenic microorganisms thanks to pattern recognition receptors (PRRs)⁴ that recognize intrinsic microbial molecular “signatures” (1). These immune receptors have been selected during evolution for their ability to bind to essential, conserved, structural components of the microorganisms such as flagellins, peptidoglycans of bacteria, lipopolysaccharides of Gram-negative bacteria, lipoteichoic acids of Gram-positive bacteria, and β-glucans of the fungal cell wall (2, 3). Examples of mammalian PRRs include Toll-like receptors (4), intracellular receptors of the NOD family (5), peptidoglycan recognition proteins (PGRPs) (6), and the membrane-bound Dectin-1 receptor, which detects fungal β-glucans (7).One important arm of the innate immunity in Drosophila is a potent systemic response that relies on the synthesis in the fat body (a functional equivalent of the mammalian liver) of potent antimicrobial peptides (AMPs) that are secreted in the hemolymph where they attack invading microorganisms. Genetic analysis has delineated two major regulatory pathways of NF-κB type that control the expression of AMP genes (8). The immune deficiency (imd) pathway is mostly required in the host defense against Gram-negative bacteria (9) and is triggered by PRRs of the PGRP family, namely PGRP-LC (10) and PGRP-LE (11). The Toll pathway is essential for fighting fungal and some Gram-positive bacterial infections (12, 13). Toll, the funding member of the Toll-like receptor family, is not itself a PRR. Rather, it is activated by a ligand of the nerve growth factor family, the Spätzle cytokine. To bind to the Toll receptor, Pro-Spätzle needs to be proteolytically processed by a protease, the Spätzle-processing enzyme (SPE) (14), which is itself activated by upstream proteolytic cascades. One such cascade is activated in response to a Gram-positive bacterial challenge by a complex of PGRP-SA, PGRP-SD, and Gram-negative binding protein 1 (GNBP1) (13, 15, 16). Flies deficient for either PGRP-SA or GNBP1 are deficient in Toll pathway activation and are susceptible to infections by several Gram-positive bacterial species but not to fungal infections. In contrast, flies mutant for GNBP3, another gene encoding a GNBP family member, fail to activate the Toll pathway in response to killed fungi and succumb rapidly to fungal but not bacterial infections (17). GNBP3 is thought to activate a proteolytic cascade, which partially overlaps that triggered by the GNBP1·PGRP-SA complex (18). Even though they belong to the same family and activate the same pathway, GNBP1 and GNBP3 are required for sensing distinct classes of microorganisms.The founding member of the GNBP family, a 50-kDa protein found in hemolymph of Bombyx mori and originally named p50, was characterized as a gram-negative (Escherichia coli) binding protein (19); hence, its name. However, it has become clear that GNBPs belong to the family of β-glucan recognition proteins (βGRP) that had first been purified on their ability to trigger the prophenol oxidase cascade (a wound response that leads to melanization at the injury site) in response to fungal infections (20). Members of the GNBP/βGRP family are extracellular proteins composed of a small N-terminal domain of about 100 residues and a longer C-terminal domain of about 350 residues (21, 22). In the insect Plodia interpunctella, both domains of βGRP bind to laminarin, a soluble β-1,3-glucan with a high affinity (K_A in the 10⁸ m⁻¹ range) (23) which is in the same range as that of the Factor G of the Japanese horseshoe crab (24). The latter factor is used as a diagnostic reagent for the detection of glucans. The C-terminal domain displays sequence similarity to bacterial glucanases, yet the catalytic residues have not been conserved, suggesting that this domain has been selected during evolution for its ability to bind to glucans (21, 22). The N-terminal domain defines a novel β-1,3-glucan binding domain that binds to curdlan, an insoluble linear β-1,3-glucan polymer, a property that the C-terminal glucanase-like domain lacks (21). Full-length recombinant GNBP/βGRPs have been reported to bind to bacteria, lipopolysaccharides, or lipoteichoic acids (19, 22, 23, 25). Although the domain(s) that mediates these interactions has not been thoroughly mapped, it appears that the N-terminal P. interpunctella β-1,3-glucan domain is not required for binding to these bacterial compounds (23).Numerous three-dimensional structures of PGRPs, in some cases complexed with their ligands, have been reported (26–29). In contrast, this knowledge is currently lacking as regarding GNBPs. As a first step toward elucidating the structure/function relationships of GNBPs, we report here that a recombinant polypeptide encoding the N-terminal domain of GNBP3 binds to fungi and to long β-1,3-glucan chains but not to short laminarioligosaccharides. The determination of the crystal structure of GNBP3 N-terminal domain reveals an immunoglobulin fold in which the β-glucan binding site is masked by a lid, which is likely to be displaced by long polysaccharide chains.