Ovocalyxin-36 Is a Pattern Recognition Protein in Chicken Eggshell Membranes

The avian eggshell membranes are essential elements in the fabrication of the calcified shell as a defense against bacterial penetration. Ovocalyxin-36 (OCX-36) is an abundant avian eggshell membrane protein, which shares protein sequence homology to bactericidal permeability-increasing protein (BPI), lipopolysaccharide-binding protein (LBP) and palate, lung and nasal epithelium clone (PLUNC) proteins. We have developed an efficient method to extract OCX-36 from chicken eggshell membranes for purification with cation and anion exchange chromatographies. Purified OCX-36 protein exhibited lipopolysaccharide (LPS) binding activity and bound lipopolysaccharide (LPS) from Escherichia coli O111:B4 in a dose-dependent manner. OCX-36 showed inhibitory activity against growth of Staphylococcus aureus ATCC 6538. OCX-36 single nucleotide polymorphisms (SNPs) were verified at cDNA 211 position and the corresponding proteins proline-71 (Pro-71) or serine-71 (Ser-71) were purified from eggs collected from genotyped hens. A significant difference between Pro-71 and Ser-71 OCX-36 for S. aureus lipoteichoic acid (LTA) binding activity was detected. The current study is a starting point to understand the innate immune role that OCX-36 may play in protection against bacterial invasion of both embryonated eggs (relevant to avian reproductive success) and unfertilized table eggs (relevant to food safety).     

Parental Transfer of the Antimicrobial Protein LBP/BPI Protects Biomphalaria glabrata Eggs against Oomycete Infections

Vertebrate females transfer antibodies via the placenta, colostrum and milk or via the egg yolk to protect their immunologically immature offspring against pathogens. This evolutionarily important transfer of immunity is poorly documented in invertebrates and basic questions remain regarding the nature and extent of parental protection of offspring. In this study, we show that a lipopolysaccharide binding protein/bactericidal permeability increasing protein family member from the invertebrate Biomphalaria glabrata (BgLBP/BPI1) is massively loaded into the eggs of this freshwater snail. Native and recombinant proteins displayed conserved LPS-binding, antibacterial and membrane permeabilizing activities. A broad screening of various pathogens revealed a previously unknown biocidal activity of the protein against pathogenic water molds (oomycetes), which is conserved in human BPI. RNAi-dependent silencing of LBP/BPI in the parent snails resulted in a significant reduction of reproductive success and extensive death of eggs through oomycete infections. This work provides the first functional evidence that a LBP/BPI is involved in the parental immune protection of invertebrate offspring and reveals a novel and conserved biocidal activity for LBP/BPI family members.     

Functional roles of SPLUNC1 in the innate immune response against Gram-negative bacteria

PLUNC (palate, lung and nasal epithelium clone)-associated gene originally referred to one gene, but now has been extended to represent a gene family that consists of a number of genes with peptide sequence homologies and predicted structural similarities. PLUNC-like proteins display sequence homology with BPI (bactericidal/permeability-increasing protein), a 456-residue cationic protein produced by precursors of polymorphonuclear leucocytes that have been shown to possess both bactericidal and LPS (lipopolysaccharide)-binding activities. The human PLUNC is also known as LUNX (lung-specific X protein), NASG (nasopharyngeal carcinoma-related protein) and SPURT (secretory protein in upper respiratory tract). The gene originally named PLUNC is now recognized as SPLUNC1. Its gene product SPLUNC1 is a secretory protein that is abundantly expressed in cells of the surface epithelium in the upper respiratory tracts and secretory glands in lung, and in the head and the neck region. The functional role of SPLUNC1 in innate immunity has been suggested but not clearly defined. The present review describes recent findings that support antimicrobial and anti-inflammatory functions of SPLUNC1 in Gram-negative bacteria-induced respiratory infection.     

PLUNC: a multifunctional surfactant of the airways

PLUNC (palate, lung and nasal epithelium clone) protein is an abundant secretory product of epithelia throughout the mammalian conducting airways. Despite its homology with the innate immune defence molecules BPI (bactericidal/permeability-increasing protein) and LBP (lipopolysaccharide-binding protein), it has been difficult to define the functions of PLUNC. Based on its marked hydrophobicity and expression pattern, we hypothesized that PLUNC is an airway surfactant. We found that purified recombinant human PLUNC exhibited potent surfactant activity by several different measures, and experiments with airway epithelial cell lines and primary cultures indicate that native PLUNC makes a significant contribution to the overall surface tension in airway epithelial secretions. Interestingly, we also found that physiologically relevant concentrations of PLUNC-inhibited Pseudomonas aeruginosa biofilm formation in vitro without acting directly as a bactericide. This finding suggests that PLUNC protein may inhibit biofilm formation by airway pathogens, perhaps through its dispersant properties. Our data, along with reports from other groups on activity against some airway pathogens, expand on an emerging picture of PLUNC as a multifunctional protein, which plays a novel role in airway defences at the air/liquid interface.     

Cloning of ovocalyxin-36, a novel chicken eggshell protein related to lipopolysaccharide-binding proteins, bactericidal permeability-increasing proteins, and plunc family proteins

The avian eggshell is a composite biomaterial composed of noncalcifying eggshell membranes and the overlying calcified shell matrix. The shell is deposited in a uterine fluid where the concentration of different protein species varies at different stages of its formation. The role of avian eggshell proteins during shell formation remains poorly understood, and we have sought to identify and characterize the individual components in order to gain insight into their function during elaboration of the eggshell. In this study, we have used direct sequencing, immunochemistry, expression screening, and EST data base mining to clone and characterize a 1995-bp full-length cDNA sequence corresponding to a novel chicken eggshell protein that we have named Ovocalyxin-36 (OCX-36). Ovocalyxin-36 protein was only detected in the regions of the oviduct where egg-shell formation takes place; uterine OCX-36 message was strongly up-regulated during eggshell calcification. OCX-36 localized to the calcified eggshell predominantly in the inner part of the shell, and to the shell membranes. BlastN data base searching indicates that there is no mammalian version of OCX-36; however, the protein sequence is 20-25% homologous to proteins associated with the innate immune response as follows: lipopolysaccharide-binding proteins, bactericidal permeability-increasing proteins, and Plunc family proteins. Moreover, the genomic organization of these proteins and OCX-36 appears to be highly conserved. These observations suggest that OCX-36 is a novel and specific chicken eggshell protein related to the superfamily of lipopolysaccharide-binding proteins/bactericidal permeability-increasing proteins and Plunc proteins. OCX-36 may therefore participate in natural defense mechanisms that keep the egg free of pathogens.     

Bactericidal/permeability-increasing protein has endotoxin-neutralizing activity

Neutrophil granules contain proteins important in host defense against bacterial pathogens. Granule proteins released from activated neutrophils facilitate opsonization, phagocytosis, tissue digestion, and antimicrobial activity. Three similar, if not identical, neutrophil proteins, bactericidal/permeability-increasing protein (BPI), 57,000 m.w. cationic antimicrobial protein, and bactericidal protein have been described that specifically kill gram negative bacteria. Since LPS is a structure common to all gram-negative bacteria, we investigated whether the microbicidal protein BPI affects biologic activity of LPS in vitro. Human neutrophils can be activated both in vitro and in vivo by LPS. Upon stimulation, surface expression of CR1 and CR3 increases markedly. Using flow microfluorimetry, we analyzed surface expression of CR1 and CR3 as a measure of neutrophil stimulation in response to LPS. CR up-regulation on neutrophils was TNF independent, suggesting direct LPS stimulation of neutrophils in this system. Purified BPI completely inhibited CR up-regulation on neutrophils stimulated with both rough and smooth LPS chemotypes at 1.8 to 3.6 nM (100 to 200 ng/ml). By comparison, the polypeptide antibiotic polymyxin B completely inhibited the same dose of LPS at 0.4 nM. The inhibitory activity of BPI appeared to be specific for LPS because neutrophil stimulation by formylated peptide or TNF was unaffected. The specificity of BPI for LPS was further demonstrated by inhibition of LPS activity in the limulus amebocyte lysate assay. Therefore, the role of BPI in infection may not be limited to its microbicidal activity, but it may also regulate the neutrophil response to LPS.     

The role of bactericidal/permeability-increasing protein as a natural inhibitor of bacterial endotoxin.

Systemic release of endotoxin (LPS) after Gram-negative infection initiates a cascade of host cytokines that are thought to be the direct cause of shock, multisystem organ failure, and death. Endogenous LPS-binding proteins may play a role in regulating LPS toxicity in vivo. The human neutrophil granule protein bactericidal/permeability-increasing protein (BPI) shares sequence homology and immunocrossreactivity with an acute phase lipopolysaccharide binding protein (LBP) which has been shown to bind to LPS and accelerate LPS activation of neutrophils and macrophages. Although structurally similar, LBP and BPI are apparently functionally antagonistic. We previously showed that BPI inhibits LPS-mediated neutrophil activation in vitro. Here we demonstrate that BPI binds to LPS near the lipid A domain, and formation of the LPS-BPI complex abrogates detrimental host responses to LPS. For example, BPI blocks LPS-stimulated TNF release in vitro and in vivo, and LPS complexed to BPI is not pyrogenic in rabbits. Results demonstrating that BPI is released by stimulated human neutrophils further support the idea that BPI functions extracellularly in vivo to neutralize endotoxin. Taken together, these data argue that BPI neutralizes the toxic effects of LPS in vivo, and that BPI may represent a new therapeutic approach to the treatment of endotoxic shock.     

The BSP30 salivary proteins from cattle,LUNX/PLUNC and von Ebner's minor salivary gland protein are members of the PSP/LBP superfamily of proteins

Saliva influences rumen function in cattle, yet the biochemical role for most of the bovine salivary proteins (BSPs) has yet to be established. Two cDNAs (BSP30a and BSP30b) from bovine parotid salivary gland were cloned and sequenced, each coding for alternate forms of a prominent protein in bovine saliva. The BSP30 cDNAs share 96% sequence identity with each other at the DNA level and 83% at the amino acid level, and appear to arise from separate genes. The predicted BSP30a and BSP30b proteins share 26-36% amino acid identity with parotid secretory protein (PSP) from mouse, rat and human. BSP30 and PSP are in turn more distantly related to a wider group of proteins that includes lung-specific X protein, also known as palate, lung, and nasal epithelium clone (LUNX/PLUNC), von Ebner's minor salivary gland protein (VEMSGP), bactericidal permeability increasing protein (BPI), lipopolysaccharide binding protein (LBP), cholesteryl ester transfer protein (CETP), and the putative olfactory ligand-binding proteins RYA3 and RY2G5. Bovine cDNAs encoding homologs of LUNX/PLUNC and VEMSGP were isolated and sequenced. Northern blot analysis showed that LUNX/PLUNC, BSP30 and VEMSGP are expressed in bovine salivary tissue and airways, and that they have non-identical patterns of expression in these tissues. The expression of both BSP30a and BSP30b is restricted to salivary tissue, but within this tissue they have distinct patterns of expression. The proximity of the human genes coding for the PSP/LBP superfamily on HSA20q11.2, their similar amino acid sequence, and common exon segmentation strongly suggest that these genes evolved from a common ancestral gene. Furthermore, they imply that the BSP30a and BSP30b proteins may have a function in common with other members of this gene family.     

Recombinant eggshell ovocalyxin-32: expression, purification and biological activity of the glutathione S-transferase fusion protein

The avian eggshell is a highly ordered biomineral composed mainly of calcium carbonate associated with an organic matrix composed of proteins, glycoproteins and proteoglycans. This structure provides the developing embryo with protection from physical damage and microbial invasion. Ovocalyxin-32 (OCX-32) is a 32 kDa eggshell-specific matrix protein which has been cloned and demonstrates 30% identity with the mammalian carboxypeptidase inhibitor, latexin. In order to further study its function, recombinant OCX-32 protein was expressed in E. coli. The protein was extracted from inclusion bodies and purified by sequential DEAE Sepharose and Ni2+ metal ion affinity chromatographies as a 58 kDa GST-fusion protein. The refolded GST-OCX-32 significantly inhibited bovine carboxypeptidase and also inhibited the growth of Bacillus subtilis. The results suggest that OCX-32 may show similar activity to the fusion protein and reinforce the antimicrobial properties of the eggshell by providing protection to the developing avian embryo. OCX-32 is the first example of an eggshell specific protein to be successfully cloned and expressed in a prokaryotic system. The association of an antimicrobial protease inhibitor with the outer eggshell and cuticle of the table egg may enhance the food safety of this product.     

The BPI/LBP family of proteins: a structural analysis of conserved regions.

Two related mammalian proteins, bactericidal/permeability-increasing protein (BPI) and lipopolysaccharide-binding protein (LBP), share high-affinity binding to lipopolysaccharide (LPS), a glycolipid found in the outer membrane of gram-negative bacteria. The recently determined crystal structure of human BPI permits a structure/function analysis, presented here, of the conserved regions of these two proteins sequences. In the seven known sequences of BPI and LBP, 102 residues are completely conserved and may be classified in terms of location, side-chain chemistry, and interactions with other residues. We find that the most highly conserved regions lie at the interfaces between the tertiary structural elements that help create two apolar lipid-binding pockets. Most of the conserved polar and charged residues appear to be involved in inter-residue interactions such as H-bonding. However, in both BPI and LBP a subset of conserved residues with positive charge (lysines 42, 48, 92, 95, and 99 of BPI) have no apparent structural role. These residues cluster at the tip of the NH2-terminal domain, and several coincide with residues known to affect LPS binding; thus, it seems likely that these residues make electrostatic interactions with negatively charged groups of LPS. Overall differences in charge and electrostatic potential between BPI and LBP suggest that BPI''s bactericidal activity is related to the high positive charge of its NH2-terminal domain. A model of human LBP derived from the BPI structure provides a rational basis for future experiments, such as site-directed mutagenesis and inhibitor design.     

The carboxyl-terminal domain of closely related endotoxin-binding proteins determines the target of protein-lipopolysaccharide complexes.

The bactericidal/permeability increasing (BPI) and lipopolysaccharide (LPS)-binding (LBP) proteins are closely related two-domain proteins in which LPS binding is mediated by the NH(2)-terminal domain. To further define the role of the COOH-terminal domain of these proteins in delivery of LPS to specific host acceptors, we have compared interactions of LBP, BPI, LBP(N)-BPI(C) (NH(2)-terminal domain of LBP, COOH-terminal domain of BPI), and BPI(N)-LBP(C) with purified (3)H-LPS and, subsequently, with purified leukocytes and soluble (s)CD14. The COOH-terminal domain of LBP promotes delivery of LPS to CD14 on both polymorphonuclear leukocytes and monocytes resulting in cell activation. In the presence of Ca(2+) and Mg(2+), LBP and BPI each promote aggregation of LPS to protein-LPS aggregates of increased size (apparent M(r) > 20 x 10(6) Da), but only LPS associated with LBP and BPI(N)-LBP(C) is disaggregated in the presence of CD14. BPI and LBP(N)-BPI(C) promote apparently CD14-independent LPS association to monocytes without cell activation. These findings demonstrate that the carboxyl-terminal domain of these closely related endotoxin-binding proteins dictates the route and host responses to complexes they form with endotoxin.     

Distant cousins: genomic and sequence diversity within the BPI fold-containing (BPIF)/PLUNC protein family

PLUNC (palate, lung and nasal epithelium clone) proteins make up the largest branch of the BPI (bactericidal/permeability-increasing protein)/LBP (lipopolysaccharide-binding protein) family of lipid-transfer proteins. PLUNCs make up one of the most rapidly evolving mammalian protein families and exhibit low levels of sequence similarity coupled with multiple examples of species-specific gene acquisition and gene loss. Vertebrate genomes contain multiple examples of genes that do not meet our original definition of what is required to be a member of the PLUNC family, namely conservation of exon numbers/sizes, overall protein size, genomic location and the presence of a conserved disulfide bond. This suggests that evolutionary forces have continued to act on the structure of this conserved domain in what are likely to be functionally important ways.     

LBP/BPI proteins and their relatives: conservation over evolution and roles in mutualism

LBP [LPS (lipopolysaccharide)-binding protein] and BPI (bactericidal/permeability-increasing protein) are components of the immune system that have been principally studied in mammals for their involvement in defence against bacterial pathogens. These proteins share a basic architecture and residues involved in LPS binding. Putative orthologues, i.e. proteins encoded by similar genes that diverged from a common ancestor, have been found in a number of non-mammalian vertebrate species and several non-vertebrates. Similar to other aspects of immunity, such as the activity of Toll-like receptors and NOD (nucleotide-binding oligomerization domain) proteins, analysis of the conservation of LBPs and BPIs in the invertebrates promises to provide insight into features essential to the form and function of these molecules. This review considers state-of-the-art knowledge in the diversity of the LBP/BPI proteins across the eukaryotes and also considers their role in mutualistic symbioses. Recent studies of the LBPs and BPIs in an invertebrate model of beneficial associations, the Hawaiian bobtail squid Euprymna scolopes' alliance with the marine luminous bacterium Vibrio fischeri, are discussed as an example of the use of non-vertebrate models for the study of LBPs and BPIs.     

新的天然免疫保护分子SPLUNC1的结构与功能研究进展

腭、肺及鼻咽上皮克隆(palate,lung,and nasal epithelium clone,PLUNC) 家族为一新近发现的具有宿主防御功能的蛋白质家族,它们大多存在于呼吸道上皮与消化道上皮的表面,在上皮组织与外界各种信号之间起着信号传递中介与信号执行分子的作用．在迄今为止发现的人类10个PLUNC家族成员中,我们所克隆的NASG基因即为这一免疫保护分子家族的成员,对其结构与功能分析表明,它属于SPLUNC1 (short palate,lung,and nasal epithelium clone 1) 的全新转录本,具有杀菌/ 渗透增强蛋白质结构域,能对外来物理及化学刺激做出反应,并具有抗微生物、清除有害化学物质、抗肿瘤等多重功效．SPLUNC1 作为上呼吸道的一种新的天然免疫保护分子,在维持上呼吸道的正常生理活动以及抗炎杀菌抑瘤中起着重要作用．     

Protein fusions of BPI with CETP retain functions inherent to each

Cholesteryl ester transfer protein (CETP), bactericidal/permeability inducing protein (BPI), and lipopolysaccharide binding protein (LBP) are members of the lipid transfer/lipopolysaccharide binding protein (LT/LBP) family of proteins that share a common secondary/tertiary structure. Despite this commonality of structure, very different patterns of lipid binding and protein-protein interactions are observed among the family members. BPI was previously shown to retain aspects of its own function when part of it was fused with LBP to form a chimeric protein. We have extended those observations to CETP. Some aspects of cholesteryl ester transfer function can be maintained in a chimeric protein even when over 40% of the sequence is from BPI. Further replacement of an additional 60 amino acids resulted in a complete loss of CETP function even though the chimera was able to retain some BPI-like properties. These artificial fusions retain BPI functions such as lipopolysaccharide (LPS) binding and protein-protein interactions that are not observed with native CETP. BPI-CETP chimeras are inhibited by LPS but cannot be inhibited by small molecule CETP inhibitors as effectively as native CETP. These results localize the site of LPS binding in BPI to a region no larger than the amino terminal 155 amino acids. This region can participate in some protein-protein interactions similar to intact BPI. Chimeras containing the amino terminus of CETP and the carboxy terminus of BPI did not retain any observable CETP function. These results further confirm the modular nature of the LT/LBP family of proteins but also highlight the discrete nature of their individual functions.     

Cloning and characterization of the homolog of mammalian lipopolysaccharide-binding protein and bactericidal permeability-increasing protein in rainbow trout Oncorhynchus mykiss

We cloned two cDNAs denoted as RT-LBP/BPI-1 and RT-LBP/BPI-2, respectively, which were derived from the mRNA of head kidney from rainbow trout. They showed structural homology with LPS-binding protein (LBP) and bactericidal/permeability-increasing protein (BPI) in mammals. The full-length cDNA of RT-LBP/BPI-1 and RT-LBP/BPI-2 is 1666 and 1741 bp, respectively. Both cDNAs encoded 473 aa residues, including the amino acids conserved in mammalian LBP and BPI proteins that were assumed to be involved in LPS binding. The overall coding sequence of RT-LBP/BPI-1 has 33% amino acid homology to human LBP and 34% to human BPI, and RT-LBP/BPI-2 has 32% amino acid homology to human LBP and 33% to human BPI. Three-dimensional structure analysis by three-dimensional/one-dimensional (3D-1D) methods also demonstrated that RT-LBP/BPI-1 and RT-LBP/BPI-2 proteins showed significant similarity to human BPI, having a boomerang shape with N-terminal and C-terminal barrels. Phylogenetic analysis showed that the LBP and BPI genes seemed to be established after the divergence of mammals from teleosts. These results suggested that RT-LBP/BPI-1 and RT-LBP/BPI-2 may be a putative ortholog for mammalian LBP and/or BPI genes. This is the first study to identify the LBP family genes from nonmammalian vertebrates.     

Characterization of the cDNA encoding a BPI/LBP homologue in venom gland of the hundred-pace snake Deinagkistrodon acutus

Bactericidal/permeability-increasing protein(BPI)and LPS-binding protein(LBP)play an important role in host defence.Current evidence shows that BPI/LBP may be widely existed in different cells and tissue types of animals.A full-length cDNA clone encoding a BPI/LBP homologue(dBPI),1757 bp in size,was characterized in venom gland of the hundred-pace snake Deinagkistrodon acutus.Its deduced amino acid sequence of 417 residues had 13.8%-21.5% identity to BPI like 1(BPIL1)and BPI like 3(BPIL3)of other animals.Co...     

Bioinformatics of the TULIP domain superfamily

Proteins of the BPI (bactericidal/permeability-increasing protein)-like family contain either one or two tandem copies of a fold that usually provides a tubular cavity for the binding of lipids. Bioinformatic analyses show that, in addition to its known members, which include BPI, LBP [LPS (lipopolysaccharide)-binding protein)], CETP (cholesteryl ester-transfer protein), PLTP (phospholipid-transfer protein) and PLUNC (palate, lung and nasal epithelium clone) protein, this family also includes other, more divergent groups containing hypothetical proteins from fungi, nematodes and deep-branching unicellular eukaryotes. More distantly, BPI-like proteins are related to a family of arthropod proteins that includes hormone-binding proteins (Takeout-like; previously described to adopt a BPI-like fold), allergens and several groups of uncharacterized proteins. At even greater evolutionary distance, BPI-like proteins are homologous with the SMP (synaptotagmin-like, mitochondrial and lipid-binding protein) domains, which are found in proteins associated with eukaryotic membrane processes. In particular, SMP domain-containing proteins of yeast form the ERMES [ER (endoplasmic reticulum)-mitochondria encounter structure], required for efficient phospholipid exchange between these organelles. This suggests that SMP domains themselves bind lipids and mediate their exchange between heterologous membranes. The most distant group of homologues we detected consists of uncharacterized animal proteins annotated as TM (transmembrane) 24. We propose to group these families together into one superfamily that we term as the TULIP (tubular lipid-binding) domain superfamily.     

Time-resolved fluoroimmunoassay for bactericidal/permeability-increasing protein

Bactericidal/permeability-increasing protein (BPI) is a cationic antimicrobial protein produced by polymorphonuclear leukocytes, that specifically interacts with and kills Gram-negative bacteria. BPl competes with lipopolysaccharide-binding protein (LBP) secreted by liver cells into blood plasma for binding to lipopolysaccharide (LPS) and thus reduces the proinflammatory effects of LPS. We have developed a time-resolved fluoroimmunoassay for BPI and measured the concentration of BPI in human serum and plasma samples. The assay is based on a rabbit antibody against recombinant BPI. This antibody specifically adheres to polymorphonuclear leukocytes in immunostained human tissues. The difference in the serum concentration of BPI between unselected hospitalized patients with and without an infection was statistically significant. The mean concentration of BPI in serum samples was 28.3 mug/l (range 1.64-132, S.D. 26.8, n = 83). In contrast, there was no difference between the two groups in the BPI levels in plasma samples. For all individuals tested, BPI levels were consistently higher in plasma samples compared to the matched serum samples. The mean concentration of BPI in plasma samples was 52.3 mug/l (range 0.9-403, S.D. 60.6, n = 90). There was a positive correlation between the concentration of BPI and the white blood cell count as well as between the BPI concentration and C-reactive protein (CRP) in serum samples. In conclusion, the present study demonstrates that BPI can be quantified reliably by time-resolved fluoroimmunoassay in human serum samples.