N-linked glycosylations at Asn(26) and Asn(114) of human MD-2 are required for toll-like receptor 4-mediated activation of NF-kappaB by lipopolysaccharide.

MD-2 is physically associated with Toll-like receptor 4 (TLR4) and is required for TLR4-mediated LPS signaling. Western blotting analysis revealed the presence of three forms of human (h)MD-2 with different electrophoretic mobilities. After N-glycosidase treatment of the cellular extract prepared from cells expressing hMD-2, only a single form with the fastest mobility was detected. Mutation of either one of two potential glycosylation sites (Asn(26) and Asn(114)) of MD-2 resulted in the disappearance of the slowest mobility form, and only the fastest form was detected in hMD-2 carrying mutations at both Asn(26) and Asn(114). Although these mutants were expressed on the cell surface and maintained its ability to associate with human TLR4, these mutations or tunicamycin treatment substantially impaired the ability of MD-2 to complement TLR4-mediated activation of NF-kappaB by LPS. LPS binding to cells expressing CD14, TLR4, and MD-2 was unaffected by these mutations. These observations demonstrate that hMD-2 undergoes N-linked glycosylation at Asn(26) and Asn(114), and that these glycosylations are crucial for TLR4-mediated signal transduction of LPS.     

Lysines 128 and 132 enable lipopolysaccharide binding to MD-2, leading to Toll-like receptor-4 aggregation and signal transduction

Three cell-surface proteins have been recognized as components of the mammalian signaling receptor for bacterial lipopolysaccharide (LPS): CD14, Toll-like receptor-4 (TLR4), and MD-2. Biochemical and visual studies shown here demonstrate that the role of CD14 in signal transduction is to enhance LPS binding to MD-2, although its expression is not essential for cellular activation. These studies clarify how MD-2 functions: we found that MD-2 enables TLR4 binding to LPS and allows the formation of stable receptor complexes. MD-2 must be bound to TLR4 on the cell surface before binding can occur. Consequently, TLR4 clusters into receptosomes (many of which are massive) that recruit intracellular toll/IL-1/resistance domain-containing adapter proteins within minutes, thus initiating signal transduction. TLR4 activation correlates with the ability of MD-2 to bind LPS, as MD-2 mutants that still bind TLR4, but are impaired in the ability to bind LPS, conferred a greatly blunted LPS response. These findings help clarify the earliest events of TLR4 triggering by LPS and identify MD-2 as an attractive target for pharmacological intervention in endotoxin-mediated diseases.     

Regions of the mouse CD14 molecule required for toll-like receptor 2- and 4-mediated activation of NF-kappa B

Regions of mouse CD14 required for Toll-like receptor 2 (TLR2)- and TLR4-mediated activation of NF-kappaB were studied in transiently transfected 293 cells. Wild-type CD14 enhanced lipopolysaccharide (LPS)-induced NF-kappaB-dependent reporter activity in cells expressing TLR4/MD-2, and deletion of amino acid regions 35-44, 144-153, 235-243, and 270-275 impaired the TLR4-mediated activation. Unlike human CD14, mouse CD14 truncated at amino acid 151 lost the activity. Deletion of amino acids 35-44 or 235-243 also abrogated TLR2-mediated activation of NF-kappaB, whereas mutants lacking 144-153 and 270-275 retained the activity. Deletion and alanine substitution experiments revealed that amino acids 151-153 and 273-275 were required for the TLR4-mediated activation. Both deletion mutants lacking amino acids 35-44 and 235-243 and alanine substitution mutants in regions 151-153 and 273-275 were expressed on the cell surface and retained the ability to associate with TLR4. A cross-linking study with photoreactive LPS showed that the labeling intensities to CD14 mutants/TLR4/MD-2 were paralleled by the ability of CD14 mutants to increase TLR4-mediated activation. These results indicate that different regions of mouse CD14 are required for TLR4- and TLR2-mediated activation of NF-kappaB and suggest that amino acids 35-44, 151-153, 235-243, and 273-275 of mouse CD14 play an important role in LPS binding and its transfer to TLR4/MD-2.     

Toll-like receptor 4 region Glu24-Lys47 is a site for MD-2 binding: importance of CYS29 and CYS40

Toll-like receptor 4 (TLR4) is a signaling receptor for lipopolysaccharide (LPS), but its interaction with MD-2 is required for efficient responses to LPS. Previous studies with deletion mutants indicate a critical role of the amino-terminal TLR4 region in interaction with MD-2. However, it is uncertain which region in the TLR4 molecule directly binds to MD-2. The purpose of this study was to determine a critical stretch of primary sequence in the TLR4 region that directly binds MD-2 and is critical for LPS signaling. The synthetic TLR4 peptide corresponding to the TLR4 region Glu(24)-Lys(47) directly binds to recombinant soluble MD-2 (sMD-2). The TLR4 peptide inhibited the binding of a recombinant soluble form of the extracellular TLR4 domain (sTLR4) to sMD-2 and significantly attenuated LPS-induced NF-kappaB activation and IL-8 secretion in wild type TLR4-transfected cells. Reduction and S-carboxymethylation of sTLR4 abrogated its association with sMD-2. The TLR4 mutants, TLR4(C29A), TLR4(C40A), and TLR4(C29A,C40A), were neither co-precipitated with MD-2 nor expressed on the cell surface and failed to transmit LPS signaling. These results demonstrate that the TLR4 region Glu(24)-Lys(47) is a site for MD-2 binding and that Cys(29) and Cys(40) within this region are critical residues for MD-2 binding and LPS signaling.     

Lipopolysaccharide is in close proximity to each of the proteins in its membrane receptor complex. transfer from CD14 to TLR4 and MD-2

The structural features of some proteins of the innate immune system involved in mediating responses to microbial pathogens are highly conserved throughout evolution. Examples include members of the Drosophila Toll (dToll) and the mammalian Toll-like receptor (TLR) protein families. Activation of Drosophila Toll is believed to occur via an endogenous peptide rather than through direct binding of microbial products to the Toll protein. In mammals there is a growing consensus that lipopolysaccharide (LPS) initiates its biological activities through a heteromeric receptor complex containing CD14, TLR4, and at least one other protein, MD-2. LPS binds directly to CD14 but whether LPS then binds to TLR4 and/or MD-2 is not known. We have used transient transfection to express human TLRs, MD-2, or CD14 alone or in different combinations in HEK 293 cells. Interactions between LPS and these proteins were studied using a chemically modified, radioiodinated LPS containing a covalently linked, UV light-activated cross-linking group ((125)I-ASD-Re595 LPS). Here we show that LPS is cross-linked specifically to TLR4 and MD-2 only when co-expressed with CD14. These data support the contention that LPS is in close proximity to the three known proteins of its membrane receptor complex. Thus, LPS binds directly to each of the members of the tripartite LPS receptor complex.     

Mutational analysis of membrane and soluble forms of human MD-2

Toll-like receptor 4 and MD-2 form a receptor for lipopolysaccharide (LPS), a major constituent of Gram-negative bacteria. MD-2 is a 20-25-kDa extracellular glycoprotein that binds to Tolllike receptor 4 (TLR4) and LPS and is a critical part of the LPS receptor. Here we have shown that the level of MD-2 expression regulates TLR4 activation by LPS. Using site-directed mutagenesis, we have found that glycosylation has no effect on MD-2 function as a membrane receptor for LPS. We used alanine-scanning mutagenesis to identify regions of human MD-2 that are important for TLR4 and LPS binding. We found that mutation in the N-terminal 46 amino acids of MD-2 did not substantially diminish LPS activation of Chinese hamster ovary (CHO) cells co-transfected with TLR4 and mutant MD-2. The residues 46-50 were important for LPS activation but not LPS binding. The residues 79-83, 121-124, and 125-129 are identified as important in LPS activation but not surface expression of membrane MD-2. The function of soluble MD-2 is somewhat more sensitive to mutation than membrane MD-2. Our results suggest that the 46-50 and 127-131 regions of soluble MD-2 bind to TLR4. The region 79-120 is not involved in LPS binding but affects monomerization of soluble MD-2 as well as TLR4 binding. We define the LPS binding region of monomeric soluble MD-2 as a cluster of basic residues 125-131. Studies on both membrane and soluble MD-2 suggest that domains of MD-2 for TLR4 and LPS binding are separate as well as overlapping. By mapping these regions on a three-dimensional model, we show the likely binding regions of MD-2 to TLR4 and LPS.     

Roles of N-linked glycans in the recognition of microbial lipopeptides and lipoproteins by TLR2

Details of roles of carbohydrates attached to Toll-like receptors (TLRs) in the recognition of pathogen-associated molecular patterns and in the formation of the functional receptor complex still remain unknown. This study was designed to determine whether the glycans linked at Asn114, Asn199, Asn414 and Asn442 residues of TLR2 ectodomain were involved in the recognition of diacylated lipopeptide and lipoprotein. Single and multiple mutants were transfected into human embryonic kidney (HEK) 293 cells together with a NF-kappaB luciferase reporter plasmid. All of these mutants were expressed on the surface. SDS-PAGE of the transfectants demonstrated that these mutants migrated lower than wild-type TLR2 and their molecular masses decreased as the number of mutated Asn residues increased. TLR2(N114A), TLR2(N199A) and TLR2(N414A) as well as wild-type TLR2 induced NF-kappaB activation when stimulated with these ligands, whereas TLR2(N442A) failed to induce NF-kappaB activation. All of triple and quadruple mutants failed to induce NF-kappaB activation, but were associated with both wild-type TLR2 and TLR6 in the transfectants. TLR2(N114A,N199A), TLR2(N114A,N414A) and, to a lesser extent, TLR2(N114A,N442A), in which two N-linked glycans are speculated to be exposed to the concave surface of TLR2 solenoid, not only induce NF-kappaB activation but also are associated with wild-type TLR2 and TLR6. These results suggest that the glycan at Asn442 and at least two N-linked glycans speculated to be exposed to the concave surface of TLR2 solenoid are involved in the recognition of ligands by TLR2 and/or in formation or maturation of a functional TLR2 receptor complex.     

The Toll-like receptor 4 region Glu24-Pro34 is critical for interaction with MD-2

Toll-like receptor 4 (TLR4) is a signaling receptor for lipopolysaccharide (LPS) but requires MD-2, a molecule associated with the extracellular TLR4 domain, to respond efficiently to LPS. The purpose of this study was to determine the critical stretch of primary sequence in the TLR4 region involved in MD-2 recognition. TLR4 and TLR4/2a chimera consisting of the TLR4 region Met(1)-Phe(54) and the TLR2 region Ala(53)-Ser(784) were coprecipitated with MD-2, but the deletion mutant TLR4(Delta E24-P34) in which the TLR4 region Glu(24)-Pro(34) was deleted failed to coprecipitate. In agreement with the MD-2 binding, LPS-conjugated beads sedimented TLR4 and TLR4/2a chimera but not TLR2 with MD-2. TLR4(Delta E24-P34) barely coprecipitated with LPS-beads. The cells that had been cotransfected with TLR4(Delta E24-P34) and MD-2 did not induce NF-kappa B activation in response to LPS. These results clearly demonstrate that the amino-terminal TLR4 region of Glu(24)-Pro(34) is critical for MD-2 binding and LPS signaling.     

Novel roles in human MD-2 of phenylalanines 121 and 126 and tyrosine 131 in activation of Toll-like receptor 4 by endotoxin

Potent mammalian cell activation by Gram-negative bacterial endotoxin requires sequential protein-endotoxin and protein-protein interactions involving lipopolysaccharide-binding protein, CD14, MD-2, and Toll-like receptor 4 (TLR4). TLR4 activation requires simultaneous binding of MD-2 to endotoxin (E) and the ectodomain of TLR4. We now describe mutants of recombinant human MD-2 that bind TLR4 and react with E.CD14 but do not support cellular responsiveness to endotoxin. The mutants F121A/K122A MD-2 and Y131A/K132A MD-2 react with E.CD14 only when co-expressed with TLR4. Single mutants K122A and K132A each react with E.CD14 +/- TLR4 and promote TLR4-dependent cell activation by endotoxin suggesting that Phe(121) and Tyr(131) are needed for TLR4-independent transfer of endotoxin from CD14 to MD-2 and also needed for TLR4 activation by bound E.MD-2. The mutant F126A MD-2 reacts as well as wild-type MD-2 with E.CD14 +/- TLR4. E.MD-2(F126A) binds TLR4 with high affinity (K(d) approximately 200 pm) but does not activate TLR4 and instead acts as a potent TLR4 antagonist, inhibiting activation of HEK/TLR4 cells by wild-type E.MD-2. These findings reveal roles of Phe(121) and Tyr(131) in TLR4-independent interactions of human MD-2 with E.CD14 and, together with Phe(126), in activation of TLR4 by bound E.MD-2. These findings strongly suggest that the structural properties of E.MD-2, not E alone, determine agonist or antagonist effects on TLR4.     

Functional activity of MD-2 polymorphic variant is significantly different in soluble and TLR4-bound forms: decreased endotoxin binding by G56R MD-2 and its rescue by TLR4 ectodomain

MD-2 is an essential component of endotoxin (LPS) sensing, binding LPS independently and when bound to the ectodomain of the membrane receptor TLR4. Natural variation of proteins involved in the LPS-recognition cascade such as the LPS-binding protein, CD14, and TLR4, as well as proteins involved in intracellular signaling downstream of LPS binding, affect the cellular response to endotoxin and host defense against bacterial infections. We now describe the functional properties of two nonsynonymous coding polymorphisms of MD-2, G56R and P157S, documented in HapMap. As predicted from the MD-2 structure, the P157S mutation had little or no effect on MD-2 function. In contrast, the G56R mutation, located close to the LPS-binding pocket, significantly decreased cellular responsiveness to LPS. Soluble G56R MD-2 showed markedly reduced LPS binding that was to a large degree rescued by TLR4 coexpression or presence of TLR4 ectodomain. Thus, cells that express TLR4 without MD-2 and whose response to LPS depends on ectopically produced MD-2 were most affected by expression of the G56R variant of MD-2. Coexpression of wild-type and G56R MD-2 yielded an intermediate phenotype with responses to LPS diminished to a greater extent than that resulting from expression of the D299G TLR4 polymorphic variant.     

Regulatory roles for MD-2 and TLR4 in ligand-induced receptor clustering

LPS, a principal membrane component in Gram-negative bacteria, is recognized by a receptor complex consisting of TLR4 and MD-2. MD-2 is an extracellular molecule that is associated with the extracellular domain of TLR4 and has a critical role in LPS recognition. MD-2 directly interacts with LPS, and the region from Phe(119) to Lys(132) (Arg(132) in mice) has been shown to be important for interaction between LPS and TLR4/MD-2. With mouse MD-2 mutants, we show in this study that Gly(59) was found to be a novel critical amino acid for LPS binding outside the region 119-132. LPS signaling is thought to be triggered by ligand-induced TLR4 clustering, which is also regulated by MD-2. Little is known, however, about a region or an amino acid in the MD-2 molecule that regulates ligand-induced receptor clustering. MD-2 mutants substituting alanine for Phe(126) or Gly(129) impaired LPS-induced TLR4 clustering, but not LPS binding to TLR4/MD-2, demonstrating that ligand-induced receptor clustering is differentially regulated by MD-2 from ligand binding. We further show that dissociation of ligand-induced receptor clustering and of ligand-receptor interaction occurs in a manner dependent on TLR4 signaling and requires endosomal acidification. These results support a principal role for MD-2 in LPS recognition.     

Glycosylation affects agonist binding and signal transduction of the rat somatostatin receptor subtype 3.

The somatostatin receptor subtypes, sst1-sst5, bind their natural ligands, somatostatin-14, somatostatin-28 and cortistatin-17, with high affinity but do not much discriminate between them. Detailed understanding of the interactions between these receptors and their peptide ligands may facilitate the development of selective compounds which are needed to identify the biological functions of individual receptor subtypes. The influence of the amino-terminal domain and of the two putative N-linked glycosylation sites located in this region of rat sst3 was analysed. Biochemical studies in transfected cell lines suggested that the amino-terminus of sst3 is glycosylated at both sites. Mutation of the N-linked glycosylation site, Asn18Thr, had only a small effect on binding properties and inhibition of adenylyl cyclase. The double mutant Asn18Thr/Asn31Thr lacking both glycosylation sites showed a significant reduction in high affinity binding and inhibition of adenylyl cyclase while peptide selectivity was not affected. Truncation of the amino-terminal region by 32 amino acid residues including the two glycosylation sites caused similar but much stronger effects. Immunocytochemical analysis of receptor localisation revealed that the amino-terminal domain but not the carbohydrates appear to be involved in the transport of the receptor polypeptide to the cell surface.     

Interaction of soluble form of recombinant extracellular TLR4 domain with MD-2 enables lipopolysaccharide binding and attenuates TLR4-mediated signaling

TLRs have been implicated in recognition of pathogen-associated molecular patterns. TLR4 is a signaling receptor for LPS, but requires MD-2 to respond efficiently to LPS. The purposes of this study were to examine the interactions of the extracellular TLR4 domain with MD-2 and LPS. We generated soluble forms of rTLR4 (sTLR4) and TLR2 (sTLR2) lacking the putative intracellular and transmembrane domains. sTLR4 consisted of Glu(24)-Lys(631). MD-2 bound to sTLR4, but not to sTLR2 or soluble CD14. BIAcore analysis demonstrated the direct binding of sTLR4 to MD-2 with a dissociation constant of K(D) = 6.29 x 10(-8) M. LPS-conjugated beads precipitated MD-2, but not sTLR4. However, LPS beads coprecipitated sTLR4 and MD-2 when both proteins were coincubated. The addition of sTLR4 to the medium containing the MD-2 protein significantly attenuated LPS-induced NF-kappaB activation and IL-8 secretion in wild-type TLR4-expressing cells. These results indicate that the extracellular TLR4 domain-MD-2 complex is capable of binding LPS, and that the extracellular TLR4 domain consisting of Glu(24)-Lys(631) enables MD-2 binding and LPS recognition to TLR4. In addition, the use of sTLR4 may lead to a new therapeutic strategy for dampening endotoxin-induced inflammation.     

Structural model of MD-2 and functional role of its basic amino acid clusters involved in cellular lipopolysaccharide recognition

The receptor complex resulting from association of MD-2 and the ectodomain of Toll-like receptor 4 (TLR4) mediates lipopolysaccharide (LPS) signal transduction across the cell membrane. We prepared a tertiary structure model of MD-2, based on the known structures of homologous lipid-binding proteins. Analysis of circular dichroic spectra of purified bacterially expressed MD-2 indicates high content of beta-type secondary structure, in agreement with the structural model. Bacterially expressed MD-2 was able to confer LPS responsiveness to cells expressing TLR4 despite lacking glycosylation. We identified several clusters of basic residues on the surface of MD-2. Mutation of each of two clusters encompassing the residues Lys(89)-Arg(90)-Lys(91) and Lys(125)-Lys(125) significantly decreased the signal transduction of the respective MD-2 mutants either upon co-expression with TLR4 or upon addition as soluble protein into the supernatant of cells overexpressing TLR4. These basic clusters lie at the edge of the beta-sheet sandwich, which in cholesterol-binding protein connected to Niemann-Pick disease C2 (NPC2), dust mite allergen Der p2, and ganglioside GM2-activator protein form a hydrophobic pocket. In contrast, mutation of another basic cluster composed of Arg(69)-Lys(72), which according to the model lies further apart from the hydrophobic pocket only weakly decreased MD-2 activity. Furthermore, addition of the peptide, comprising the surface loop between Cys(95) and Cys(105), predicted by model, particularly in oxidized form, decreased LPS-induced production of tumor necrosis factor alpha and interleukin-8 upon application to monocytic cells and fibroblasts, respectively, supporting its involvement in LPS signaling. Our structural model of MD-2 is corroborated by biochemical analysis and contributes to the unraveling of molecular interactions in LPS recognition.     

Separate functional domains of human MD-2 mediate Toll-like receptor 4-binding and lipopolysaccharide responsiveness

Cellular responses to LPS are mediated by a cell surface receptor complex consisting of Toll-like receptor 4 (TLR4), MD-2, and CD14. MD-2 is a secreted protein that interacts with the extracellular portion of TLR4. Site-directed mutagenesis was used to identify the regions of human MD-2 involved in its ability to bind TLR4 and confer LPS responsiveness. A separate region of MD-2 was found to mediate each function. MD-2 binding to TLR4 was dependent on Cys(95) and Cys(105), which might form an intramolecular disulfide bond. Hydrophilic and charged residues surrounding this area, such as R90, K91, D100, and Y102, also contributed to the formation of the TLR4-MD-2 complex. A different region of MD-2 was found to be responsible for conferring LPS responsiveness. This region is not involved in TLR4 binding and is rich in basic and aromatic residues, several of which cooperate for LPS responsiveness and might represent a LPS binding site. Disruption of the endogenous MD-2-TLR4 complex by expression of mutant MD-2 inhibited LPS responses in primary human endothelial cells. Thus, our data indicate that MD-2 interaction with TLR4 is necessary but not sufficient for cellular response to LPS. Either of the two functional domains of MD-2 can be disrupted to impair LPS responses and therefore represent attractive targets for therapeutic interventions.     

Kinetics of binding of LPS to recombinant CD14, TLR4, and MD-2 proteins

TLR4 together with CD14 and MD-2 forms a pattern recognition receptor that plays an initiating role in the innate immune response to Gram-negative bacteria. Here, we employed the surface plasmon resonance technique to investigate the kinetics of binding of LPS to recombinant CD14, MD-2 and TLR4 proteins produced in insect cells. The dissociation constants (KD) of LPS for immobilized CD14 and MD-2 were 8.7 microM, and 2.3 microM, respectively. The association rate constant (Kon) of LPS for MD-2 was 5.61 x 10(3) M-1S-1, and the dissociation rate constant (Koff) was 1.28 10 2 S 1, revealing slow association and fast dissociation with an affinity constant KD of 2.33 x 10-6 M at 25 degreesC. These affinities are consistent with the current view that CD14 conveys LPS to the TLR4/MD-2 complex.     

CD36 Differently Regulates Macrophage Responses to Smooth and Rough Lipopolysaccharide

Lipopolysaccharide (LPS) is the major pathogen-associated molecular pattern of Gram-negative bacterial infections, and includes smooth (S-LPS) and rough (R-LPS) chemotypes. Upon activation by LPS through CD14, TLR4/MD-2 heterodimers sequentially induce two waves of intracellular signaling for macrophage activation: the MyD88-dependent pathway from the plasma membrane and, following internalization, the TRIF-dependent pathway from endosomes. We sought to better define the role of scavenger receptors CD36 and CD204/SR-A as accessory LPS receptors that can contribute to pro-inflammatory and microbicidal activation of macrophages. We have found that CD36 differently regulates activation of mouse macrophages by S-LPS versus R-LPS. The ability of CD36 to substitute for CD14 in loading R-LPS, but not S-LPS onto TLR4/MD-2 allows CD14-independent macrophage responses to R-LPS. Conversely, S-LPS, but not R-LPS effectively stimulates CD14 binding to CD36, which favors S-LPS transfer from CD14 onto TLR4/MD-2 under conditions of low CD14 occupancy with S-LPS in serum-free medium. In contrast, in the presence of serum, CD36 reduces S-LPS binding to TLR4/MD-2 and the subsequent MyD88-dependent signaling, by mediating internalization of S-LPS/CD14 complexes. Additionally, CD36 positively regulates activation of TRIF-dependent signaling by both S-LPS and R-LPS, by promoting TLR4/MD-2 endocytosis. In contrast, we have found that SR-A does not function as a S-LPS receptor. Thus, by co-operating with CD14 in both R- and S-LPS loading onto TLR4/MD-2, CD36 can enhance the sensitivity of tissue-resident macrophages in detecting infections by Gram-negative bacteria. However, in later phases, following influx of serum to the infection site, the CD36-mediated negative regulation of MyD88-dependent branch of S-LPS-induced TLR4 signaling might constitute a mechanism to prevent an excessive inflammatory response, while preserving the adjuvant effect of S-LPS for adaptive immunity.     

The amino-terminal region of toll-like receptor 4 is essential for binding to MD-2 and receptor translocation to the cell surface

Toll-like receptor 4 (TLR4) and MD-2 are pivotal components that elicit inflammatory responses to lipopolysaccharide (LPS). They have been shown to form a physical complex on the cell surface that responds directly to LPS. However, the functional region of TLR4 required for association with MD-2 and LPS responsiveness is poorly understood. To identify the region of TLR4, we created a series of mutants with deletions in the extracellular domain and examined their activities in human embryonic kidney 293 cells. A mutant with a 317-amino acid deletion from the membrane proximal region of TLR4 was capable of associating with MD-2, while only a 9-amino acid truncation of the N terminus severely impaired the interaction. The association between the two molecules was well correlated with TLR4 maturation into an endoglycosidase H-resistant form and the cell surface expression. Mouse MD-2 bound to human TLR4, but its activity to facilitate the cell surface expression of TLR4 and confer LPS responsiveness was much weaker than that of human MD-2, indicating species specificity. A chimeric receptor composed of the N-terminal region of human TLR4 and the adjacent region of mouse TLR4 showed preference for human MD-2 in its transport to the cell surface and responsiveness to LPS. Taken together, the N-terminal region of TLR4 is essential for association with MD-2, which is required for the cell surface expression and hence the responsiveness to LPS.     

The differential impact of disulfide bonds and N-linked glycosylation on the stability and function of CD14

Innate immunity is the first line defense against invading pathogens. During Gram-negative bacterial infection, the Toll-like receptor 4 and MD-2 complex recognize lipopolysaccharide present in the bacterial cell wall. This recognition can be enhanced 100-1000-fold by CD14. However, the beneficial role provided by CD14 becomes detrimental in the context of sepsis and septic shock. An understanding of how CD14 functions will therefore benefit treatments targeted at both immune suppression and immune enhancement. In the present study, we use site-directed mutagenesis to address the role of disulfide bonds and N-linked glycosylation on CD14. A differential impact is observed for the five disulfide bonds on CD14 folding, with the first two (Cys(6)-Cys(17) and Cys(15)-Cys(32)) being indispensable, the third and fourth (Cys(168)-Cys(198) and Cys(222)-Cys(253)) being important, and the last (Cys(287)-Cys(333)) being dispensable. A functional role is observed for the first disulfide bond because the C6A substitution severely reduces the ability of CD14 to confer lipopolysaccharide responsiveness to U373 cells. Two of the four predicted glycosylation sites, asparagines 132 and 263, are actually involved in N-linked glycosylation, resulting in heterogeneity in CD14 molecular weight. Furthermore, glycosylation at Asn(132) plays a role in CD14 trafficking and upstream and/or downstream ligand interactions. When mapped onto the crystal structure of mouse CD14, the first two disulfide bonds and Asn(132) are in close proximity to the initial beta strands of the leucine rich repeat domain. Thus, disulfide bonds and N-linked glycosylation in the initial beta sheets of the inner concave surface of CD14 are crucial for structure and function.