A homogeneous, liposome-based signal amplification for assays involving enzymes

Exploiting the fact that phosphatidylethanolamine (PE) liposome can be stabilized by a membrane lipid or protein, and that destruction of this stabilizer leads to rapid lysis of the liposome, we have designed a liposome-based signal enhancement mechanism for assays that involve enzyme as the final read-out step. Stable liposomes with entrapped glucose-6-phosphate dehydrogenase (G6PDH) were prepared with unsaturated PE stabilized with 5 mol percent of ganglioside GM1. Addition of beta-galactosidase caused rapid (3-5 min) lysis of liposomes, revealing the latent G6PDH activity, owing to the enzymatic degalactosylation of GM1. We have used Microgenic's CEDIA assay for digoxin as an example. The magnitude of signal was 25 mA/min per microgram of digoxin per liter for the unamplified assay and 1000 mA/min per microgram of digoxin per liter for the liposome-enhanced assay--i.e., a 40-fold amplification. This simple, rapid, and homogeneous signal-amplification mechanism is likely to be useful in many enzyme-dependent assays, such as ELISA, CEDIA, gene-probe assays, and immunoliposome assays.

Kinetic and ultrastructural studies of interactions of target-sensitive immunoliposomes with herpes simplex virus

The bilayer phase of dioleoylphosphatidylethanolamine (PE) can be stabilized with palmitoyl-IgG monoclonal antibody to the glycoprotein gD of the herpes simplex virus (HSV). Interactions of PE immunoliposomes with the target virions were characterized by analyzing the kinetics of lipid mixing, by liposomal content release, and by ultrastructural studies. As revealed by a resonance energy transfer assay, lipid mixing between PE immunoliposomes and virions was very rapid, with a second-order rate constant (kapp) of 0.173 (min)-1 (microgram/mL virus)-1. In comparison, content release from PE immunoliposomes was much slower and exhibited multiple-phase, mixed-order kinetics, indicating that liposome destabilization involved fusion of liposomes with HSV. The extent and the apparent rate of liposome destabilization were strongly dependent on liposome concentration. This was evident by the fact that only one to two liposomes were destabilized by each virus particle at low liposome concentration (0.1 microM). For higher liposome concentrations (1-10 microM), this value was 35-104. This finding implies that collision among the virus-bound liposomes is essential for the eventual collapse of PE immunoliposomes to form the hexagonal (HII) equilibrium phase which was observed using freeze-fracture electron microscopy. Studies employing soluble gD, immobilized on latex beads, indicated that a multivalent antigen source is essential for PE immunoliposome destabilization. Immediately after liposome-virus binding, fusion of liposome with the viral membrane then follows. Upon growth of the fusion complexes, which increase to 35-104 liposomes for each virus, an eventual collapse of the structure results, driving PE to its equilibrium structure of HII phase.

Electron microscopic observation on infected hairs of kerion caused by Microsporum nanum

Microsporum nanum can afflict human hair, although pigs are the usual focus of infection. Although this dermatophyte was thought to invade hair as an endothrix, electron microscopic studies show it to cause ectothrix infection due to its keratinolytic activities.

pH-sensitive immunoliposomes mediate target-cell-specific delivery and controlled expression of a foreign gene in mouse

A plasmid containing the Escherichia coli chloramphenicol acetyltransferase (CAT) gene under the control of a mammalian cAMP-regulated promoter was entrapped in H-2Kk antibody-coated liposomes composed of dioleoyl phosphatidylethanolamine, cholesterol, and oleic acid (pH-sensitive immunoliposomes). The entrapped or free DNA was injected intraperitoneally into immunodeficient (nude) BALB/c mice bearing ascites tumor generated by H-2Kk-positive RDM-4 lymphoma cells. About 20% of the injected immunoliposomes were taken up by the target RDM-4 cells. Uptake was much less when liposomes without antibody were used. The presence of the targeting antibody on liposomes also significantly decreased the nonspecific uptake of liposomes by the spleen. Significant CAT enzyme activity was detected in RDM-4 cells from mice treated with DNA entrapped in the pH-sensitive immunoliposomes. Furthermore, CAT expression in RDM-4 cells was under the control of cAMP, as only the cells from mice injected with 8-bromo-cAMP and 3-isobutyl-1-methylxanthine showed CAT activity. CAT activity in liver and spleen was much lower (by factors of 12 and 5, respectively) than in the RDM-4 cells, and the activities in these reticuloendothelial organs were not regulated by cAMP. CAT activity in RDM-4 cells from mice injected with DNA entrapped in pH-insensitive immunoliposomes (containing phosphatidylcholine in place of phosphatidylethanolamine) was approximately one-fourth that in RDM-4 cells from mice injected with pH-sensitive immunoliposomes, indicating the superior delivery efficiency of the pH-sensitive liposomes. These results are discussed in terms of the DNA-carrier potential of immunoliposomes in therapy of cancer and genetic diseases.

Interactions of target-sensitive immunoliposomes with herpes simplex virus. The foundation of a sensitive immunoliposome assay for the virus

Interactions between target-sensitive (TS) immunoliposomes and herpes simplex virus (HSV) were investigated. Target sensitivity of phosphatidylethanolamine (PE) immunoliposomes is a result of the ability of acylated monoclonal anti-HSV glycoprotein D (gD) to stabilize the bilayer phase of PE, whereas by itself, PE does not form stable liposomes (Ho, R. J. Y., Rouse, B. T., and Huang, L. (1986) Biochemistry 25, 5500-5506). Upon binding of these immunoliposomes to HSV antigen-containing gD, destabilization of PE immunoliposomes was observed. By encapsulating either a self-quenching fluorescent dye, calcein, or alkaline phosphatase inside the liposomal compartment, the HSV-induced destabilization of TS immunoliposomes was shown to be target-specific. Neither Sendai, Semliki Forest, nor Sindbis virus could significantly destabilize the TS immunoliposomes. Moreover, HSV-induced liposome destabilization could be inhibited by free anti-gD (the same antibody used in TS immunoliposomes) but not by monoclonal anti-HSV glycoprotein B, indicating that the interaction was antigen-specific. Destabilization could also be induced by binding to truncated gD (tgD), but only when in a multivalent form immobilized on latex beads. Truncated gD is a cloned, 312-amino acid fragment of HSV-gD that lacks the transmembrane segment. Preincubation of soluble tgD with the TS immunoliposomes failed to induce destabilization and, in addition, abolished the tgD-bead-induced destabilization. This finding strongly indicated that multivalent binding is essential for TS immunoliposome destabilization. Using alkaline phosphatase encapsulated in the liposomes, TS immunoliposomes could be used to detect HSV in fluid phase with 50% signal recorded at 5 microliters of 3.2 x 10(3) pfu/ml; at least 10-fold more sensitive than the standard double-antibody sandwich enzyme-linked immunosorbent assay. The interactions described here may be useful in designing a homogeneous and sensitive immunoliposome assay.

Target-sensitive immunoliposomes as an efficient drug carrier for antiviral activity

We have shown previously that target-sensitive immunoliposomes composed of palmitoyl antibody stabilized phosphatidylethanolamine bilayers could be destabilized by binding to the target cells (Ho, R. J. Y., Rouse, B. T., and Huang, L., Biochemistry (1986) 25, 5500-5506). Target-sensitive immunoliposome-encapsulated and free cytotoxic drugs of nucleoside analogs cytosine-beta-D-arabinoside (AraC) or acycloguanosine (acyclovir, ACV) were compared for their antiviral efficacy and cell cytotoxicity. Target-insensitive immunoliposomes and nontargeted liposomes were also investigated. When the mouse fibroblast L929 cells were infected at low multiplicity with herpes simplex virus, AraC encapsulated in target-sensitive immunoliposomes composed of transphosphatidylated egg phosphatidylethanolamine effectively inhibited virus replication and had far less cell cytotoxicity than free drug. As a measure of cytotoxicity, the drug concentration required to inhibit 50% of [3H]thymidine incorporation from 6 to 42 h (CD50) was determined. For free AraC, this value was 0.3 ng/ml, whereas for target-sensitive immunoliposome-encapsulated AraC, the CD50 exceeded 1 microgram/ml. However, target-sensitive immunoliposome-encapsulated AraC was virus inhibitory (50% effective dose = ED50) at 1.8 ng/ml. A free drug concentration of at least 1000-fold greater was required for comparable antiviral activity. A similar phenomenon was observed when ACV was administered via target-sensitive immunoliposomes. The CD50 values of the free and target-sensitive immunoliposome-encapsulated ACV were 12.5 ng/ml and 1.4 micrograms/ml, respectively, whereas the ED50 values of the free and target-sensitive immunoliposome-encapsulated ACV were 1.1 and 125 ng/ml, respectively. Consequently, our results indicated the superiority of target-sensitive immunoliposomes at drug delivery, especially when drugs were cytotoxic to cells. The use of liposomes of the target-insensitive variety provided some enhancement of activity, but this was several-fold less than that observed with target-sensitive immunoliposomes. In addition, the nucleoside transport inhibitors, p-nitrothiobenzylinosine and dipyridamole, were shown to inhibit the liposome-mediated antiviral activity of AraC. This finding indicated that site-specific cytosolic delivery of nucleoside analogs by target-sensitive immunoliposomes involved a cellular nucleoside transport system. A mechanism of action is proposed.

Plasmid DNA adsorbed to pH-sensitive liposomes efficiently transforms the target cells

We have previously reported that plasmid DNA entrapped in the pH-sensitive immunoliposomes effectively transforms the target cells (Proc. Natl. Acad. Sci. USA, in press). In the present study, we demonstrate that DNA adsorbed on the same liposome also transforms the target cells. The transformation activity is antibody dependent, as liposomes containing no targeting antibody had reduced activity. The activity could be significantly inhibited by excess non-specific DNA (salmon sperm). Since some DNA are likely adsorbed to the liposomes during the entrapment process, the activity of the entrapped DNA is partially accounted for by the adsorbed DNA. The possibility of developing a simple DNA-mediated transfection protocol using liposome adsorbed DNA is discussed.

L-652,469--a dual receptor antagonist of platelet activating factor and dihydropyridines from Tussilago farfara L

L-652,469, 14-acetoxy-7 beta-(3'-ethylcrotonoyloxy)-notonipetranone, isolated from the methylene chloride extracts of the buds of Tussilago farfara L, was found to inhibit both platelet activating factor (PAF) and Ca2+ entry blocker binding to membrane vesicles. It inhibits the [3H]PAF specific binding to rabbit platelet membranes with equilibrium inhibition constants (Ki) of 3.2 and 4.0 microM in the presence of 150 mM NaCl and 10 mM MgCl2 respectively. It is a competitive PAF receptor antagonist with an equilibrium dissociation constant (KB) of 5.16 microM. It also competitively inhibits the specific binding of Ca2+ channel blockers (e.g. [3H]nitrendipine; Ki = 1.2 microM) in cardiac sarcolemmal vesicles. At 10(-5) M, L-652,469 causes a 60% relaxation of Ca2+-induced contraction of rat thoracic aorta strips. Due to its dual antagonistic activities, L-652,469 potently inhibits the gel-filtered rabbit platelet aggregation with a pA2 of 5.79. It was also found to be orally active with a beneficial effect to inhibit the PAF-induced rat foot edema and the first phase of carrageenan-induced rat hindpaw edema.

Increased survival of skin flaps by scavengers of superoxide radical

Elevation of rat abdominal skin flaps, followed by ligation and division of the left inferior neurovascular pedicle, resulted in only a 40% survival of the area normally perfused by the ligated artery and vein. Superoxide dismutase (SOD) (EC 1.15.1.1) administered i.v. (20,000 U/kg) 30 min before flap elevation increased survival to 52%. SOD derivatized with polyethylene glycol, which increases circulating half-life, was more effective, increasing survival to 80%. This protective effect resulted from the catalytic activity of the derivatized enzyme because inactivation by treatment with H2O2 eliminated its effect on skin flap survival. An equimolar mixture of Desferal and MnCl2, which catalyzes the dismutation of O2- in vitro, improved survival to 72%. Desferal-Fe3+, which lacks in vitro SOD activity, or Mn2+ alone did not affect the survival of skin flaps, but Desferal alone was nearly as effective as the Desferal-Mn2+ mixture. This effect of Desferal may result from acquisition of and subsequent removal of iron in vivo. These results support the view that the superoxide radical or a product derived from it plays a role in limiting the survival of island skin flaps.

The role of multivalency in antibody mediated liposome targeting

We have investigated the role of multivalency in immunoliposome binding to cells displaying different amounts of surface antigen using liposomes with increasing numbers of palmitoyl anti-H2Kk antibodies incorporated into the bilayer. RDM-4 lymphoma cells were treated with proteinase k to generate a series of cells with various amounts of H2Kk antigen. Percent binding of immunoliposomes was related to the number of antigens displayed by the RDM-4 cell. Increasing liposome binding was observed with increasing number of antibody molecules per liposome. However, the ratio of binding of the high-antigen-density cells to that of the low-antigen-density cells was higher with immunoliposomes of lower antibody density than the ones with higher antibody density. This result suggests that for better discrimination between cells differing in antigen density, liposomes with lower numbers of antibody molecules per liposome may be more useful as a discriminatory tool for cells with a low level antigen expression than liposomes with greater antibody densities.

Thermodynamic and phase characterization of phosphatidylethanolamine and ganglioside GD1a mixtures

By employing diphenylhexatriene steady-state fluorescence anisotropy, pyrenedecanoic acid excimer formation, and high sensitivity scanning calorimetry we have demonstrated that the liposomes containing phosphatidylethanolamine (PE) and various mole fractions of ganglioside GD1a had a gel-liquid crystalline phase transition between 15 and 25 degrees C. Calorimetric measurements indicated that these phase transitions were broad and centered between 17 and 21 degrees C. The enthalpy change of the transition was linearly dependent on the ganglioside concentration up to 10.0 mol% and plateaued between 11.4-16.2 mol%. The high enthalpy change (37 kcal/mol of GD1a added into the PE bilayer) indicates the existence of PE-GD1a complex structure in the liposomal membrane. It is proposed that semi-fluid domains containing six PE and one ganglioside molecule are present in the PE-GD1a membranes at temperatures above gel-liquid crystalline phase transition. The Sendai virus induced leakage of PE-GD1a liposomes has been investigated by using an entrapped, self-quenching fluorescent dye, calcein. The leakage rate was dependent on the mole fraction of ganglioside GD1a and was maximal at 6.3 mol%. Arrhenius plots of the leakage rates showed breaks in the 20-25 degrees C temperature range, which correspond to the gel-liquid crystalline phase transition of the target liposomes. These data suggest that the rate of Sendai virus-induced leakage can be regulated via fluidity modulation by changing the PE to GD1a ratio at constant temperatures.

A putative mediator of insulin action which inhibits adenylate cyclase and adenosine 3',5'-monophosphate-dependent protein kinase: partial purification from rat liver: site and kinetic mechanism of action

A novel putative mediator of insulin action which acts to inhibit adenylate cyclase and cAMP-dependent protein kinase has been purified from livers of insulin-treated streptozotocin-diabetic rats. It was increased by short term (5-min) insulin injections in vivo and purified several thousand-fold by Sephadex and HPLC. Its mol wt was somewhat larger (2500) than previous mediators identified, and it was more hydrophobic in character. Its mechanism of action or adenylate cyclase was determined and found to be chiefly directed against the catalytic subunit. Its action on the cAMP-dependent protein kinase was found to be competitive with regard to protein substrate, but noncompetitive with regard to ATP and cAMP. Its relationship to other putative insulin mediators and the mechanism of insulin action is discussed.

Gadolinium-labeled liposomes: targeted MR contrast agents for the liver and spleen

A contrast agent for use in magnetic resonance (MR) imaging of the liver and spleen has been designed in which gadolinium-DTPA is chemically incorporated into the lamellar phase of liposome particles. This agent has excellent in vivo stability and is taken up by liver and spleen of normal mice after intravenous administration. The T1 increased by 110% in liver and 66% in spleen at 4 degrees C. At 37 degrees, the relaxation rate in the liver increased by 180%. This method is an attractive concept for the development of various organ-specific liposomal contrast agents that may be used for either MR imaging or nuclear medicine.

Solid core liposomes with encapsulated colloidal gold particles

Solid core liposomes with encapsulated colloidal gold particles were prepared through four major steps: Preparation of prevesicles with encapsulated solid cores of agarose-gelatin by emulsification of agarose-gelatin sol in organic solvent containing emulsifiers followed by cooling. Extraction of lipophilic components from prevesicles to obtain microspherules of agarose-gelatin. Introducing colloidal gold particles into microspherules and coating with protein molecules. Encapsulation of colloidal gold-bearing microspherules with the modified organic solvent spherule evaporation method for preparation of liposomes (Kim et al. (1983) Biochim. Biophys. Acta 728, 339-348 and Kim et al. (1984) Biochim. Biophys. Acta 812, 793-801). Electron micrographs showed that if liposomes were prepared by using a lipid mixture containing dioleoylphosphatidylcholine/cholesterol/dioleoylphosphatidylglycerol/tri olein (molar ratio 4.5:4.5:1:1), there was only a single continuous bilayer membrane for each solid core liposome. However, if no triolein was added to the lipid mixture, it would cause the formation of multilamellar liposomes. In both cases, there were hundreds to thousands of colloidal gold particles within each solid core liposome.

ATP-Mn2+ stimulates the generation of a putative mediator of insulin action

Substantial evidence suggests that insulin receptor-associated protein kinase may play a pivotal role in the expression of the intracellular effects of insulin. This study was undertaken to determine whether insulin receptor kinase contributes to the generation of putative insulin mediators. The effect of ATP and divalent cation addition on the production of insulin mediators from liver plasma membranes was investigated. ATP (1 mM) added to liver plasma membranes in the absence of divalent cations enhanced insulin-stimulated release/generation of mediator slightly (approximately 3-fold). ATP in the presence of Mn2+ further increased release/generation of mediator markedly (approximately 100-fold). In contrast, ATP in the presence of Mg2+ had no stimulatory effect. Mn2+ and Mg2+ alone were ineffective. Addition of EDTA completely diminished the stimulatory effects of insulin, ATP, and Mn2+. The stimulation was ATP-specific since other nucleotides and nonhydrolyzable analogues of ATP had no or very weak activity. ATP-Mn2+ stimulated insulin-dependent mediator release/generation in a dose-dependent manner. These results suggest that insulin mediator release/generation is markedly stimulated by an ATP-Mn2+-dependent phosphorylation reaction, similar to insulin-stimulated receptor tyrosine kinase phosphorylation.

Inhibition of herpes simplex virus replication in the mouse cornea by drug containing immunoliposomes

Monoclonal antibody to HSV glycoprotein D was derivatized with palmitic acid and incorporated into liposomes. These immunoliposomes bound specifically to intact mouse corneas infected with HSV-1 in vitro. Furthermore, in yield reduction assays, anti-gD immunoliposomes loaded with acyclovir proved far more effective at inhibiting viral replication in the cornea than free drug or drug delivered in untargeted liposomes. Site-specific sustained release immunoliposomes of this type are potentially an improved vehicle for drug delivery in the treatment of ocular HSV.

Cytotoxicity of diphtheria toxin A fragment to toxin-resistant murine cells delivered by pH-sensitive immunoliposomes

pH-sensitive immunoliposomes composed of dioleoylphosphatidylethanolamine and oleic acid (8:2 molar ratio) mediated the delivery of the cytotoxic fragment A of diphtheria toxin to the cytoplasm of target L-929 cells. Free fragment A, fragment A encapsulated in antibody-free liposomes, or fragment A encapsulated in pH-insensitive immunoliposomes was not effective in the inhibition of the cellular protein synthesis. pH-sensitive immunoliposomes containing diphtheria fragment A were not toxic to nontarget diphtheria-resistant A31 cells or to nontarget diphtheria-sensitive Vero cells. Pretreatment of target L-929 cells with the weak bases NH4Cl or chloroquine, agents which raise the endosome/lysosome pH, blocked the cytotoxic effect of the pH-sensitive immunoliposomes containing fragment A. Excess free antibody or excess empty pH-sensitive immunoliposomes also blocked the cytotoxic effect. Since it is known that fragment A alone cannot cross lipid membranes, the results of this study indicate that pH-sensitive immunoliposomes are able to release the toxin into the cytoplasm, probably by fusing with the endosome membrane following a receptor-mediated endocytosis of the immunoliposome.

Preparation of colloidal gold-labeled agarose-gelatin microspherules for electron microscopic studies of phagocytosis in cultured cells

Agarose-gelatin microspherules about 0.5 micron or larger are prepared with emulsification of 4% agarose-gelatin sol containing 0.2 M N-octylglucoside in an organic phase composed of cyclohexane, egg lecithin, Span 80, and ethanol, followed by extraction of lipophilic components with cyclohexane and ether. Colloidal gold particles are then introduced into microspherules using gold chloride reacting at room temperature with tannic acid in a specified concentration range. After they have been coated with bovine serum albumin or mouse IgG, colloidal gold-labeled microspherules can be readily phagocytized by mouse L-cells and P388 cells after incubation for several hours. In addition to their use as a novel marker for phagocytosis, we discuss other potential uses for these colloidal gold-labeled microspherules.