Lipopolysaccharide-binding Peptide Research Articles

Combined Delivery of a Lipopolysaccharide-Binding Peptide and the Heme Oxygenase-1 Gene Using Deoxycholic Acid-Conjugated Polyethylenimine for the Treatment of Acute Lung Injury.

A ternary complex comprising plasmid DNA, lipopolysaccharide-binding peptide (LBP), and deoxycholic acid-conjugated polyethylenimine (PEI-DA) is prepared for combinational therapy of acute lung injury (ALI). The LBP is designed as an anti-inflammatory peptide based on the lipopolysaccharide (LPS)-binding domain of HMGB-1. In vitro cytokine assays show that LBP reduces levels of proinflammatory cytokines by inhibiting LPS. PEI-DA is synthesized as the gene carrier by conjugation of deoxycholic acid to low-molecular weight polyethylenimine (2 kDa, PEI2k). PEI-DA has higher transfection efficiency than high-molecular weight polyethylenimine (25 kDa, PEI25k). The ternary complex of an HO-1 plasmid (pHO-1), PEI-DA, and LBP is prepared as a combinational system to deliver the therapeutic gene and peptide. The transfection efficiency of the ternary complex is higher than that of the pHO-1/PEI-DA binary complex. The ternary complex also reduces TNF-α secretion in LPS-activated Raw264.7 macrophage cells. Administration of the ternary complex into the lungs of an animal ALI model by intratracheal injection induces HO-1 expression and reduces levels of proinflammatory cytokines more efficiently than the pHO-1/PEI-DA binary complex or LBP alone. In addition, the ternary complex reduces inflammation in the lungs. Therefore, the pHO-1/PEI-DA/LBP ternary complex may be an effective treatment for ALI.

Colorimetric detection of lipopolysaccharides based on a lipopolysaccharide-binding peptide and AuNPs

A facile colorimetric assay for the detection of lipopolysaccharides (LPSs) was proposed based on a LPS-binding peptide and AuNPs.

Targeting the lipopolysaccharides: still a matter of debate?

The intention of this article is to review endotoxin, host response to endotoxin, clinical significance of endotoxemia, past failed therapies targeting endotoxin, current therapeutic efforts in this area and the authors' opinion on the future of such therapy. Endotoxin or lipopolysaccharide is implicated in the activation of cytokine release with the potential to lead to severe sepsis. Therapies targeting endotoxin are very appealing and remain a matter of study and debate. Antiendotoxin antibody studies did not show consistent benefit to warrant its approval for use. Lipid A analog, phospholipid emulsion, and ethyl pyruvate are currently being evaluated for potential clinical use. Polymyxin B as an antiendotoxin strategy has an unacceptable toxicity profile for routine use as an intravenous agent and its use in plasmapheris is too cumbersome. Curcumin and lipopolysaccharide binding peptides, although having a potentially desirable effect on ameliorating endotoxin toxicity, remain to be shown effective in clinical trials. The development of a vaccine against endotoxin carries promise. The benefits of therapies targeting endotoxin remain to be elucidated. Clinical trials targeting populations with documented endotoxemia are more likely to provide an adequate test of this therapeutic approach. Prophylaxis of high-risk populations should also be considered.

An Improved Phage Display Procedure for Identification of Lipopolysaccharide-Binding Peptides

We successfully implemented several modifications to the regular phage display procedure and significantly improved the lipopolysaccharides-binding properties of the peptides selected. Specifically, the number of biopannings was increased and peptides with consensus sequences were obtained. A dual selection procedure (referred to as subtractive panning) was used to simultaneously select for the desired target and deselect for an undesired target, thereby increasing the binding specificity. In addition, binding and washing conditions in the subtractive panning were also modified to favor the selection of peptides with higher binding strength. As a result, two peptides, ASFPPAF and SSHTISF, were identified with much improved binding properties compared to those selected with regular panning. The binding specificities of these two peptides, as measured by the ratio of phages bound to the desired and undesired targets, were severalfold higher than previously reported. These modifications could easily be implemented with many other target molecules, indicating the general applicability of the procedure.

A Synthetic Lipopolysaccharide-Binding Peptide Based on Amino Acids 27–39 of Serum Amyloid P Component Inhibits Lipopolysaccharide-Induced Responses in Human Blood

LPS-binding proteins in plasma play an important role in modifying LPS toxicity. Significant properties have already been attributed to the LPS-binding protein (LBP). It accelerates LPS toxicity as well as incorporation into high-density lipoproteins, leading to neutralization of LPS in serum. A search for other LPS-binding components in serum, using LPS-coated magnetic beads, revealed a new LPS-binding protein. N-terminal microsequencing identified this protein as serum amyloid P component (SAP). Purified SAP bound to smooth and rough types of LPS via the lipid A part. SAP inhibited the binding of FITC-labeled ReLPS (LPS from Salmonella minnesota strain R595) to human monocytes and the ReLPS-induced priming of the oxidative burst of human neutrophils only in the presence of low concentrations of LBP. In search for the LPS binding site of SAP, we found that pep27-39, a 13-mer peptide consisting of amino acids 27-39 of SAP, competitively inhibited the binding of LPS to SAP. In addition, pep27-39 significantly inhibited ReLPS-induced responses in phagocytes in the presence of serum, as well as in human whole blood. Carboxamidomethylated pep27-39 showed an even more pronounced reduction of the ReLPS-induced priming of phagocytes in human blood. Performing gel filtration of FITC-labeled ReLPS incubated with soluble CD14, we showed that SAP could not prevent binding of LPS to soluble CD14, in contrast to pep27-39. The ability of pep27-39 to antagonize specifically the effects of LPS in the complex environment of human blood suggests that pep27-39 may be a novel therapeutic agent in the treatment of gram-negative sepsis.

A synthetic lipopolysaccharide-binding peptide based on the neutrophil-derived protein CAP37 prevents endotoxin-induced responses in conscious rats.

The lipid A component of lipopolysaccharide (LPS) derived from Escherichia coli has been implicated as a significant mediator in the development of circulatory and metabolic dysfunction and lethality associated with sepsis. A synthetic peptide corresponding to amino acid residues 20 through 44 of the neutrophil-derived 37-kDa cationic antimicrobial protein (CAP37 P(20-44)) possesses lipid A binding characteristics which may be useful in attenuating in vivo responses induced during circumstances of endotoxemia, including sepsis. The E. coli LPS to be used in the in vivo study was shown to be attenuated by CAP37 P(20-44) in a dose-dependent manner in the in vitro reaction with Limulus amoebocyte lysate. Intravenous infusion of CAP37 P(20-44) (1.5 or 3.0 mg/kg of body weight) with E. coli LPS (250 microg/kg over 30 min) into conscious, unrestrained rats prevented LPS-induced hyperdynamic and hypodynamic circulatory shock, hyperlactacidemia, and leukopenia in a dose-related fashion. CAP37 P(20-44) (0.2, 1.0, and 5.0 mg/kg) administered intravenously to conscious, actinomycin D-sensitized rats following a lethal dose of LPS neutralized LPS toxicity, resulting in dose-dependent 7-day survival rates of 30, 50, and 80%, respectively. CAP37 P(20-44) (5.0 mg/kg) significantly inhibited the endotoxin-induced increase in circulating tumor necrosis factor alpha in sensitized rats. These data demonstrate that CAP37 P(20-44) has the capacity to abolish in vivo biological responses to LPS that are relevant to human sepsis and to significantly neutralize the toxicity of circulating E. coli LPS.

Synthesis and properties of tachyplesin I, a lipopolysaccharide-binding peptide, from Tachypleus tridentatus

Tachyplesin I, a cationic heptadecapeptide amide containing two disulfide bonds isolated from hemocytes of Tachypleus tridentatus, which binds to lipopolysaccharide, was synthesized by a solid-phase procedure. Reduction and oxidation of the deprotected peptide amide yielded an identical peptide to native tachyplesin I in terms of chemical and biological properties. Tachyplesin 1 was found to bind to alkylphosphorylcholine accompanied by perturbation of its tyrosyl and tryptophyl residues but bound only weakly to N-acetyl-D-glucosamine tetramer.