The interaction of endotoxin aggregates with phospholipid liposomes of different composition was investigated applying fluorescence polarization spectroscopy with the fluorophore diphenylhexatriene and the resonance energy transfer technique using N-(7-nitro-2,1,3-benzoxadiazol-4-yl)-PE and N-(Rhodamine B sulfonyl)-PE. Fluorescence polarization data at constant temperature could be interpreted in favor of an intercalation of lipopolysaccharide into phospholipid liposomes even in the absence of Ca2+. Intercalation, however, could be clearly excluded from determinations performed as a function of temperature. Experiments employing the resonance energy transfer technique clearly showed that a nonspecific, hydrophobic intercalation of endotoxin aggregates into phospholipid liposomes only takes place in the presence of excess molar concentrations of divalent cations and/or after long-term incubation at elevated temperature (37°C). These findings indicate that under (near) physiological conditions nonspecific intercalation of aggregated lipopolysaccharide into phospholipid membranes represents an unlikely event. The significance of these results for an understanding of the fundamental mechanisms of cell activation by endotoxin is discussed.
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References
1.
Freudenberg MA, Meier-Dieter U., Staehelin T., Galanos C.Analysis of lipopolysaccharide released from Salmonella abortus equi in human serum. Microb Pathogen1991; 10: 93-104.
2.
Johnston CA, Greisman SEEndotoxemia induced by antibiotic therapy: a mechanism for adrenal corticosteroid protection in Gram-negative sepsis. Trans Assoc Am Physicians1984; 97: 172-181.
3.
Rietschel ET , Kirikae T., Schade FU et al. Bacterial endotoxin: molecular relationships of structure to activity and function. FASEB J1994; 8: 217-225.
4.
Rietschel ET , Brade H., Holst O. et al. Bacterial endotoxin: chemical constitution, biological recognition, host response, and immunological detoxification. Curr Top Microbiol Immunol1995; In press.
5.
Hailman E., Lichenstein HS, Wurfel MM et al. Lipopolysaccharide (LPS)-binding protein accelerates the binding of LPS to CD14. J Exp Med1994; 179: 269-277.
6.
Morrison DC, Lei MG, Kirikae T., Chen TYEndotoxin receptors on mammalian cells. Immunobiology1993; 187: 212-226.
7.
Chen TY, Lei MG, Suzuki T., Morrison DCLipopolysaccharide receptors and signal transduction pathways in mononuclear phagocytes. Curr Top Microbiol Immunol1992 ; 181: 170-188.
8.
Ulevitch RJRecognition of bacterial endotoxins by receptor-dependent mechanisms. Adv Immunol1993; 53: 267-289.
9.
Tobias PS, Ulevitch RJLipopolysaccharide binding protein and CD14 in lipopolysaccharide dependent macrophage activation. Immunobiology1993; 187: 227-232.
10.
Schumann RRFunction of lipopolysaccharide (LPS)-binding protein (LBP) and CD14, the receptor for LPS/LBP complexes: a short review . Res Immunol1992; 143: 11-15.
11.
Arditi M., Zhou J., Dorio R., Rong GW, Goyert SM, Kim KSEndotoxin-mediated endothelial cell injury and activation: role of soluble CD14. Infect Immun1993; 61: 3149-3156.
12.
Pugin J., Schiirer-Maly C-C., Leturcq D., Moriarty A., Ulevitch RJ, Tobias PSLipopolysaccharide activation of human endothelial and epithelial cells is mediated by lipopolysaccharide-binding protein and soluble CD14. Proc Natl Acad Sci USA1993; 90: 2744-2748.
13.
Lynn WA, Liu Y., Golenbock DTNeither CD14 nor serum is absolutely necessary for activation of mononuclear phagocytes by bacterial lipopolysaccharide. Infect Immun1993; 61: 4452-4461.
14.
Couturier C. , Jahns G., Kazatchkine MD, Haeffner-Cavaillon N.Membrane molecules which trigger the production of interleukin-1 and tumor necrosis factor-α by lipopolysaccharide-stimulated human monocytes. Eur J Immunol1992;22: 1461-1466.
15.
Corrales I. , Weersink Ajl, Verhoef J., Van Kessel KPM.Serum-independent binding of lipopolysaccharide to human monocytes is trypsin sensitive and does not involve CD14. Immunology1993; 80:84-89.
16.
Kirkland TN , Finley F., Leturcq D. et al. Analysis of lipopolysaccharide binding by CD14. J Biol Chem1993; 268: 24818-24823.
17.
Kabir S., Rosenstreich DL, Mergenhagen SEBacterial endotoxin and cell membranes. In: Jeljaszewic J, Wadstrøm T, eds. Bacteria Toxins and Cell Membranes. New York: Academic Press, 1978: 59-87.
18.
Portoles MT , Pagani R., Diaz-Laviada I., Municio AMEffect of Escherichia coli lipopolysaccharide on the microviscosity of liver plasma membranes and hepatocyte suspensions and monolayers. Cell Biochem Funct1987; 5: 55-61.
19.
Jacobs DM, Yeh H., Price RMFluorescent detection of lipopolysaccharide interactions with model membranes . Adv Exp Med Biol1990; 256: 233-245.
20.
Price RM, Jacobs DMFluorescent detection of lipopolysaccharide interactions with model membranes . Biochim Biophys Acta1986; 859: 26-32.
21.
Jackson SK, James PE, Rowlands CC, Mile B.Binding of endotoxin to macrophages; interactions of spin-labelled saccharide residues. Biochim Biophys Acta1992; 1135: 165-170.
22.
Brandenburg K., Mayer H., Koch Mhj, Weckesser J., Rietschel ET, Seydel U.Influence of the supramolecular structure of free lipid A on its biological activity. Eur J Biochem1993; 218: 555-563.
23.
Seydel U., Labischinski H., Kastowsky M., Brandenburg K.Phase behavior, supramolecular structure, and molecular conformation of lipopolysaccharide . Immunobiology1993; 187: 191-211.
24.
Shnyra A., Hultenby K., Lindberg AARole of the physical state of Salmonella lipopolysaccharide in expression of biological and endotoxic properties. Infect Immun1993; 61: 5351-5360.
25.
Takayama K. , Mitchell DH, Din ZZ, Mukerjee P., Li C., Coleman DLMonomeric Re lipopolysaccharide from Escherichia coli is more active than the aggregated form in the Limulus amebocyte lysate assay and in inducing Egr-1 mRNA in murine peritoneal macrophages. J Biol Chem1994; 269: 2241-2244.
26.
Takayama K. , Din ZZ, Mukerjee P., Cooke PH, Kirkland TNPhysicochemical properties of the lipopolysaccharide unit that activates B lymphocytes. J Biol Chem1990; 265: 14023-14029.
27.
Zannoni C., Arcioni A., Cavatorta P.Fluorescence depolarization in liquid crystals and membrane bilayers. Chem Phys Lipids1983; 32:179-250.
28.
Struck DK, Hoekstra D., Pagano REUse of resonance energy transfer to monitor membrane fusion. Biochemistry1981; 20: 4093-4099.
29.
Gregoridias G. , ed. Liposome Technology. Vol. I: Preparation of liposomes. BocaRaton: CRC Press , 1984.
30.
Düzgünes N. , Allen TM, Fedor J., Papahadjopoulos D.Lipid mixing during membrane aggregation and fusion: Why fusion assays disagree. Biochemistry1987; 26: 8435-8442.
31.
Wilschut J. , Nir S., Scholrna J., Hoekstra D.Kinetics of Ca2+-induced fusion of cardiolipin-phosphatidylcholine vesicles: correlation between vesicle aggregation, bilayer destabilisation and fusion. Biochemistry1985; 24: 4630-4636.
32.
Galanos C., Lüderitz O., Westphal O.A new method for the extraction of R lipopolysaccharides. Eur J Biochem1969; 9: 245-249.
33.
Brade H., Galanos C., Lüderitz O.Differential determination of the 3-deoxy-D-mannooctulosonic acid in lipopolysaccharides of Salmonella minnesota rough mutants. Eur J Biochem1983; 131: 195-200.
34.
Kröner EE, Peskar BA, Fischer H., Ferber E.Control of arachidonic acid accumulation in bone marrow-derived macrophages by acyl transferases. J Biol Chem1981; 256: 3690-3697.
35.
Brock TG, Nagaprakash K., Margolis DI, Smolen JEModeling degranulation with liposomes: effect of lipid composition on membrane fusion. J Membr Biol1994; 141: 139-148.
36.
Smith R., Tanford C.The critical micelle concentration of L-α-dipalmitoylphosphatidylcholine in water and water/methanol solutions. J Mol Biol1972; 67: 75-83.
37.
Larsen NE, Enelow RI, Simons ER, Sullivan R.Effect of bacterial endotoxin on the transmembrane electrical potential and plasma membrane fluidity of human monocytes. Biochim Biophys Acta1985; 815: 1-8.
38.
Jacobs DM, Price RMA model for lipopolysaccharide-membrane interaction. Adv Exp Med Biol1987; 216: 691-699.
39.
Jackson SK, James PEEffects of E. coli 0111-B4 lipopolysaccharide on spin-labelled murine macrophage and hepatocyte membranes. Free Radic Res1989 ; 8: 47-53.
40.
Tobias P., Mathison J., Mintz D. et al. Participation of lipopolysaccharide-binding protein in lipopolysaccharide-dependent macrophage activation. Am J Respir Cell Mol Biol1992; 7: 239-245.
41.
Seydel U., Brandenburg K.Supramolecular structure of lipopolysaccharides and lipid A. In: Morrison DC, Ryan JL, eds. Bacterial Endotoxic Lipopolysaccharides. Vol I: Molecular Biochemistry and Cellular Biology. Boca Raton: CRC Press, 1992: 225-250.
42.
Larsen NE, Sullivan R.Interaction between endotoxin and human monocytes: characteristics of the binding of 3H-labeled lipopolysaccharide and 51Cr-labeled lipid A before and after the induction of endotoxin tolerance. Proc Natl Acad Sci USA1984; 81: 3491-3495.
43.
Tahri-Jouti MA, Chaby R.Specific binding of lipopolysaccharides to mouse macrophages. 1. Characteristics of the interaction and inefficiency of the polysaccharide region. Mol Immunol1990; 27: 751-761.
44.
Tobias PS, Soldau K., Gegner JA, Mintz D., Ulevitch RJLipopolysaccharide binding protein-mediated complexation of lipopolysaccharide with soluble CD14. J Biol Chem1995; 264: 10867-10873.
