The use of streptavidin-biotin interaction for preparation of reagents for complement-dependent liposome immunoassay of proteins: detection of latrotoxin.

We have developed liposome sensitization by a protein, latrotoxin (LT), using immobilization of biotinylated LT via streptavidin with biotinylated phosphatidylethanolamine contained in liposomes. The use of such liposomes in the complement-dependent homogeneous liposome immune lysis assay (LILA) has allowed us to detect in the test sample as little as 2 micrograms/ml of polyclonal and 50-100 ng/ml of monoclonal IgG and IgM antibodies to LT. LT concentration in solution was determined by inhibition of immune lysis by free LT. The sensitivity of the LT assay varied from 1 x 10(-9) to 5-50 x 10(-9) M when antiserum (polyclonal antibodies) and monoclonal antibodies to LT were correspondingly used. The results show that a streptavidin-biotin spacer can be used to immobilize protein antigens on liposomes for a subsequent application in LILA. The suggested technique greatly simplifies the sensitization procedure and extends the applicability of the LILA.     

A facile,sensitive and quantitative membrane‐binding assay for proteins

Soluble proteins that bind membranes function in numerous cellular pathways yet facile, sensitive and quantitative methods that complement and improve sensitivity of widely used liposomes‐based assays remain unavailable. Here, we describe the utility of a photoactivable fluorescent lipid as a generic reporter of protein‐membrane interactions. When incorporated into liposomes and exposed to ultraviolet (UV), proteins bound to liposomes become crosslinked with the fluorescent lipid and can be readily detected and quantitated by in‐gel fluorescence analysis. This modification obviates the requirement for high‐speed centrifugation spins common to most liposome‐binding assays. We refer to this assay as Proximity‐based Labeling of Membrane‐Associated Proteins (PLiMAP).     

Phospholipase A(2)-catalyzed membrane leakage studied by immobilized liposome chromatography with online fluorescent detection

Unilamellar liposomes composed of phosphatidylcholine with an entrapped self-quenching fluorescent dye, calcein, were immobilized in chromatographic gel beads by avidin-biotin binding. Bee venom phospholipase A(2) (PLA(2)) was applied in a small amount onto the immobilized liposome column. The release of calcein from the immobilized liposomes resulting from the catalyzed hydrolysis of the phospholipids was detected online by immobilized liposome chromatography (ILC) using a flow fluorescent detector. The PLA(2)-catalyzed membrane leakage of the immobilized liposomes as studied with ILC was found to be affected by the gel pore size used for immobilization, by liposome size, and as expected by the concentration of calcium, but was unaffected by the flow rate of ILC. The largest PLA(2)-induced calcein release from the liposome column was detected on large unilamellar liposomes immobilized on TSK G6000PW or Sephacryl S-1000 gel in the presence of 1 mM Ca(2+) in the aqueous mobile phase. Comparison with the PLA(2)-catalyzed membrane leakage in free liposome suspensions, we conclude that the fluorescent leakage from liposomes hydrolyzed by PLA(2) can be rapidly and sensitively detected by ILC runs using large amount of immobilized liposomes with entrapped fluorescent dye.     

Fluidity and osmotic sensitivity changes of phospholipase A2-treated liposomes

Membrane fluidity and osmotic sensitivity were examined in DPPC liposomes treated with phospholipase A2 (PL.A2) in the presence of Ca2+ or Mg2+. The amount of liposome phospholipid hydrolyzed differed with the two ions. Embedded DPH, a rod-like fluorescent probe, was employed in the determination of membrane fluidity. Membrane fluidity decreased according to the degree of phospholipid hydrolization in liposomes by PL.A2. The reciprocal value of absorption at 450 nm was measured as the index of osmotic sensitivity of liposomes. Intact sonicated liposomes showed osmotic insensitivity. PL.A2-treated liposomes in which about 40% of total phospholipid was hydrolyzed showed osmotic sensitivity. No change in the membrane fluidity was obtained when PL.A2-treated liposomes were exposed to hypertonic or hypotonic solution. These results suggested that the motion of the acyl-chain of phospholipids and free fatty acids was resisted in PL.A2-treated liposomes. The resistance may be due to a phase separation between phospholipids and free fatty acids. The pore for water permeation might be induced in the border between phase-separated domains in PL.A2-treated liposomes.     

Constant Pressure-controlled Extrusion Method for the Preparation of Nano-sized Lipid Vesicles

Liposomes are artificially prepared vesicles consisting of natural and synthetic phospholipids that are widely used as a cell membrane mimicking platform to study protein-protein and protein-lipid interactions³, monitor drug delivery^4,5, and encapsulation⁴. Phospholipids naturally create curved lipid bilayers, distinguishing itself from a micelle.⁶ Liposomes are traditionally classified by size and number of bilayers, i.e. large unilamellar vesicles (LUVs), small unilamellar vesicles (SUVs) and multilamellar vesicles (MLVs)⁷. In particular, the preparation of homogeneous liposomes of various sizes is important for studying membrane curvature that plays a vital role in cell signaling, endo- and exocytosis, membrane fusion, and protein trafficking⁸. Several groups analyze how proteins are used to modulate processes that involve membrane curvature and thus prepare liposomes of diameters <100 - 400 nm to study their behavior on cell functions³. Others focus on liposome-drug encapsulation, studying liposomes as vehicles to carry and deliver a drug of interest⁹. Drug encapsulation can be achieved as reported during liposome formation⁹. Our extrusion step should not affect the encapsulated drug for two reasons, i.e. (1) drug encapsulation should be achieved prior to this step and (2) liposomes should retain their natural biophysical stability, securely carrying the drug in the aqueous core. These research goals further suggest the need for an optimized method to design stable sub-micron lipid vesicles.Nonetheless, the current liposome preparation technologies (sonication¹⁰, freeze-and-thaw¹⁰, sedimentation) do not allow preparation of liposomes with highly curved surface (i.e. diameter <100 nm) with high consistency and efficiency^10,5, which limits the biophysical studies of an emerging field of membrane curvature sensing. Herein, we present a robust preparation method for a variety of biologically relevant liposomes.Manual extrusion using gas-tight syringes and polycarbonate membranes^10,5 is a common practice but heterogeneity is often observed when using pore sizes <100 nm due to due to variability of manual pressure applied. We employed a constant pressure-controlled extrusion apparatus to prepare synthetic liposomes whose diameters range between 30 and 400 nm. Dynamic light scattering (DLS)¹⁰, electron microscopy¹¹ and nanoparticle tracking analysis (NTA)¹² were used to quantify the liposome sizes as described in our protocol, with commercial polystyrene (PS) beads used as a calibration standard. A near linear correlation was observed between the employed pore sizes and the experimentally determined liposomes, indicating high fidelity of our pressure-controlled liposome preparation method. Further, we have shown that this lipid vesicle preparation method is generally applicable, independent of various liposome sizes. Lastly, we have also demonstrated in a time course study that these prepared liposomes were stable for up to 16 hours. A representative nano-sized liposome preparation protocol is demonstrated below.     

钙库调控的钙通道Orai1体外研究方法的建立

目的:建立钙通道Orai1的体外研究方法。方法:利用脂质体重组技术,将体外纯化的Orai1蛋白重组到脂质体膜上,利用蔗糖密度梯度离心来检测其重组效率及Orai1蛋白在脂质体膜上的结构,并利用钙染料Fura-2检测脂质体内钙离子的释放。结果:成功制备了脂质体及体外纯化了GST-Orai1融合蛋白,蔗糖密度梯度离心结果证明GST-Orai1蛋白成功重组到脂质体上,以及Orai1蛋白以多聚体的形式定位在脂质体膜上。钙离子释放实验证明脂质体内钙离子包装完好,可用于后续Orai1钙通道的功能研究。结论:利用脂质体重组技术建立了一种新的Orai1的研究方法,能够更直接有效地研究其功能及其活化机制。     

Multifunctional liposomes for nasal delivery of the anti-Alzheimer drug tacrine hydrochloride

The purpose of this study was the development of multifunctional liposomes for nasal administration of tacrine hydrochloride. Liposomes were prepared using traditional excipients (cholesterol and phosphatidylcholine), partly enriched with α-tocopherol and/or Omega3 fatty acids. This approach was chosen in order to obtain at the same time two positive results: an enhanced drug permeation through nasal mucosa and a concomitant neuroprotective effect. Several liposome formulations were prepared using the Reverse Phase Evaporation technique followed by membrane filter extrusion. In particular, liposome capacity to enhance drug permeation was evaluated by means of membrane permeation and cellular uptake studies. Furthermore, liposome effect on neuronal viability and intracellular ROS production was evaluated as well as their cytoprotective effect against oxidative stress. All liposome formulations showed a mean diameter in the range of 175?nm to 219?nm with polydispersity index lower than 0.22, a lightly negative zeta potential and excellent encapsulation efficiency. Moreover, along with good mucoadhesive properties, multifunctional liposomes showed a markedly increase in tacrine permeability, which can be related to liposome fusion with cellular membrane, a hypothesis, which was also supported by cellular uptake studies. Finally, the addition of α-tocopherol without Omega3 fatty acids, was found to increase the neuroprotective activity and antioxidant properties of liposomes.     

Interaction of pH-Sensitive Liposomes With Blood Components

Abstract

Avoidance of lysosomal degradation of drugs entrapped in liposomes has been one of the major efforts in liposome research. The achievement of high drug deliver}' efficiency using pH-sensitive liposomes over the pH-insensitive liposomes has greatly influenced our strategies in liposome drug delivery. The success of pH-sensitive liposomes in delivering compounds such as fluorescence dye, anti-cancer reagents, toxins and DNA to target cells with high efficiency in vitro shows a great potential to apply the same strategy to in vivo systems. Using human plasma as a simplified model for blood, we have systematically examined the interaction of pH-sensitive liposomes composed of dioleoylphosphatidyl-ethanolamine (DOPE) and oleic acid (OA) with plasma components. Our results show that the bilayer structure of liposomes in plasma depends on their sizes. Small liposomes (d<200nm) were stabilized by plasma components while the larger ones (d>600nm) were rapidly lysed upon the exposure to plasma. Such differences in their stability in plasma may derive from their differences in lipid packing which determines the surface pressure of the membrane. Using purified serum proteins, we found that albumin such as bovine serum albumin (BSA) lyse liposomes by extracting OA from the bilayer. However, BSA induced lysis could be blocked by lipoproteins including HDL, LDL and VLDL, but not by immunoglobulins. Further studies with purified components of HDL demonstrated that apoAl, not the lipids of the HDL, contains the stabilization activity. The extraction of OA from liposomes and the insertion of plasma components into the bilayer modified the bilayer properties such that plasma stabilized liposomes were no longer pH sensitive. Using dipalmitoylsuccinylglycerol (DPSG), a double-chain pH senser for DOPE liposomes, we could preserve 50% pH sensitivity after plasma treatment. The potential application of such liposomes and other essential properties of pH-sensitive liposomes for drug delivery in vivo are also discussed.     

The role of calcium in fusion of artificial vesicles.

Small phospholipid vesicles (liposomes) fuse upon calcium addition as demonstrated by electron microscopy, light absorbance increases, and mixing of original liposome contents within the boundaries of the fused liposome. The integrity of the fusion event is demonstrated by a novel assay based on the luminescence of firefly extract when mixed with ATP. Subsequent addition of valinomycin or the calcium ionophore A23187 leads to further fusion as shown by electron microscopy, light microscopy, and additional absorbance increase. Concomitant with this second absorbance increase is an increase in the amount of calcium that associates with the liposomes. This increased calcium association is more than can be accounted for by equilibration of 5 mM Ca2+ across the membrane and must indicate exposure of extra calcium binding sites. Binding of calcium to the inner side of the membrane may catalyze the second stage of liposome fusion.     

Rapid assay of trace immunoglobulin M by a new immunonanogold resonance scattering spectral probe

Nanogold, 8 nm in size, was used to label goat antihuman immunoglobulin M (GIgM) to obtain a new immunonanogold resonance scattering (RS) probe (Au-GIgG) for quantitation of trace immunoglobulin M (IgM). The Au-GIgG combined with IgM to form nanogold-labeled immunocomplex causes the RS intensity at 580 nm to be enhanced, in pH 4.49 KH(2)PO( 4)-Na(2)HPO(4) buffer and in the presence of polyethylene glycol 6000. The enhanced RS intensity at 580 nm (DeltaI(580 nm)) is proportional to the IgM concentration in the range of 1.5 to 2000 ng/mL, with a lower detection limit of 0.98 ng/mL. The immunonanogold RS assay was used to assay IgM in serum samples, with sensitivity, selectivity, and simplicity.     

Signal-enhancer molecules encapsulated liposome as a valuable sensing and amplification platform combining the aptasensor for ultrasensitive ECL immunoassay

An innovatory ECL immunoassay strategy was proposed to detect the newly developing heart failure biomarker N-terminal pro-brain natriuretic peptide (NT-proBNP). Firstly, this strategy used small molecules encapsulated liposome as immune label to construct a sandwich immune sensing platform for NT-proBNP. Then the ECL aptasensor was prepared to collect and detect the small molecules released from the liposome. Finally, based on the ECL signal changes caused by the small molecules, the ECL signal indirectly reflected the level of NT-proBNP antigen. In this experiment, the cocaine was chosen as the proper small molecule that can act as signal-enhancer to enhance the ECL of Ru(bpy)(3)(2+). The cocaine-encapsulated liposomes were successfully characterized by TEM. The quantificational calculation proved the ～5.3×10(3) cocaine molecules per liposome enough to perform the assignment of signal amplification. The cocaine-binding ECL aptasensor further promoted the work aimed at amplifying signal. The performance of NT-proBNP assay by the proposed strategy exhibited high sensitivity and high specificities with a linear relationship over 0.01-500 ng mL(-1) range, and a detection limit down to 0.77 pg mL(-1).     

The effect of liposomes on the growth and sensitivity of Mycobacterium smegmatis to isoniazide

The effects of the liposome form of isoniazide (IN) and liposomes without IN on the growth of Mycobacterium smegmatis were studied. Fluorescent assay demonstrated that the fraction of liposomes that interacted with M. smegmatis amounted to 1-3%. It was shown that the IN efficiency in a liposomal form decreased depending on the liposome composition and concentration as compared with the IN in water solution. A preincubation of mycobacteria with liposomes led to a decrease in their sensitivity to IN. An analogous effect was observed when incubating M. smegmatis with oleic acid. It was postulated that the relative resistance of M. smegmatis to the antibiotic when using lipids as a carbon substrate appeared due to a change in the agent's metabolism and should be taken into account when testing in vitro the liposomal forms of antibiotics.     

Avidin–biotin-immobilized liposome column for chromatographic fluorescence on-line analysis of solute–membrane interactions

Unilamellar liposomes with entrapped fluorescent dye calcein were stably immobilized in gel beads by avidin–biotin-binding. The immobilized liposomes remained extremely stable upon storage and chromatographic runs. The immobilized calcein-entrapped liposomes were utilized for fluorescent analysis of solute–membrane interactions, which in some cases are too weak to be detected by chromatographic retardation. A liposome column was used as a sensitive probe to detect the interactions of membranes with pharmaceutical drugs, peptides and proteins. Retardation of the solutes was monitored using a UV detector. Perturbation of the membranes, reflected as leakage of the entrapped calcein by some of the solutes, can thus be detected on-line using a flow-fluorescent detector. For the amphiphilic drugs or synthetic peptides, perturbation of membranes became more pronounced when the retardation (hydrophobicity) of the molecules increased. On the other hand, in the case of positively-charged peptides, polylysine, or partially denatured bovine carbonic anhydrase, significant dye leakage from the liposomes was observed although the retardation was hardly to be measured. Weak protein–membrane interactions can thus be assumed from the large leakage of calcein from the liposomes. This provides additional useful information for solute–membrane interactions, as perturbation of the membranes was also indicated by avidin–biotin-immobilized liposome chromatography (ILC).     

External surface area determination of lipid vesicles using trinitrobenzene sulfonate and ultraviolet/visible spectrophotometry

The lamellarity of liposomes is an important parameter to be controlled in liposomal delivery–release applications. A practical estimate of the degree of liposome lamellarity can be obtained by measuring the relative external surface area of the liposomes using a chemical assay. All such assays are based on a signal change caused by exposed marker lipids on reaction with a specific externally added reagent. However, a quantitative determination is often distorted by background reactions and contributions of internal lipid labeling. In the so-called TNBS assay, the marker lipid is phosphatidylethanolamine (PE) and the externally added reagent is TNBS (2,4,6-trinotrobenzene sulfonate). Mechanistic aspects of the TNBS assay were considered for improving the assay. Internal lipid labeling via PE flip-flop and/or TNBS permeation was minimal not only in cholesterol-containing liposomes but also in cholesterol-free liposomes if in the latter case membrane fluidity was decreased by slightly increasing the PE content. Compared with earlier versions of the TNBS assay, the amount of marker lipid and the time for analysis could be reduced considerably. The elaborated protocol was also applied to liposomes prepared from lipidic egg yolk isolates, offering a simple and inexpensive method for the development and in-process control of new liposome formation technologies.     

Adjuvant effects of nonionic block polymer surfactants on liposome-induced humoral immune response

The ability of several surface-active agents to stimulate the humoral immune response in mice against haptenated liposomes was tested. The surfactants were block copolymers of hydrophilic polyoxyethylene (POE) and hydrophobic polyoxypropylene (POP) that differed in m.w., percentage of POE, and mode of linkage of POP to POE. The liposomes were haptenated with tripeptide-enlarged dinitrophenyl coupled to phosphatidylethanolamine, which was incorporated into the liposomal membrane. Additional injection of mice with surfactant stimulated serum hemagglutination titers and splenic plaque-forming cell (PFC) numbers to varying extents. Block polymers with POP chains flanking a POE center, as well as polymers with POE chains flanking a POP center, displayed high adjuvant activity. These block polymers stimulated the antibody response in a dose-dependent manner. They stimulated the antibody response with both high and low antigen doses. Furthermore, the addition of one of these adjuvants (25R1) reduced the amount of carrier lipid required in the liposome in order to obtain an optimal antibody response. The surfactants, which displayed high adjuvant activity, did not interfere with liposome stability as measured with a liposome lysis assay. Moreover, in vitro preincubation of liposomes with a block polymer did not affect their immunogenicity. Optimal adjuvant activity was observed when both adjuvant and liposomes were administered by the same route. Simultaneous injection of both components, however, is not a prerequisite. Conclusively, it can be stated that nonionic block polymer surfactants are potent adjuvants for stimulation of the antibody response against haptenated liposomes.     

Reducing Liposome Size with Ultrasound: Bimodal Size Distributions

Sonication is a simple method for reducing the size of liposomes. We report the size distributions of liposomes as a function of sonication time using three different techniques. Liposomes, mildly sonicated for just 30 sec, had bimodal distributions when surface-weighted with modes at about 140 and 750 nm. With extended sonication, the size distribution remains bimodal but the average diameter of each population decreases and the smaller population becomes more numerous. Independent measurements of liposome size using Dynamic Light Scattering (DLS), transmission electron microscopy (TEM), and the nystatin/ergosterol fusion assay all gave consistent results. The bimodal distribution (even when number-weighted) differs from the Weibull distribution commonly observed for liposomes sonicated at high powers over long periods of time and suggests that a different mechanism may be involved in mild sonication. The observations are consistent with the following mechanism for decreasing liposome size. During ultrasonic irradiation, cavitation, caused by oscillating microbubbles, produces shear fields. Large liposomes that enter these fields form long tube-like appendages that can pinch-off into smaller liposomes. This proposed mechanism is consistent with colloidal theory and the observed behavior of liposomes in shear fields.     

Reducing liposome size with ultrasound: bimodal size distributions

Sonication is a simple method for reducing the size of liposomes. We report the size distributions of liposomes as a function of sonication time using three different techniques. Liposomes, mildly sonicated for just 30 sec, had bimodal distributions when surface-weighted with modes at about 140 and 750 nm. With extended sonication, the size distribution remains bimodal but the average diameter of each population decreases and the smaller population becomes more numerous. Independent measurements of liposome size using Dynamic Light Scattering (DLS), transmission electron microscopy (TEM), and the nystatin/ergosterol fusion assay all gave consistent results. The bimodal distribution (even when number-weighted) differs from the Weibull distribution commonly observed for liposomes sonicated at high powers over long periods of time and suggests that a different mechanism may be involved in mild sonication. The observations are consistent with the following mechanism for decreasing liposome size. During ultrasonic irradiation, cavitation, caused by oscillating microbubbles, produces shear fields. Large liposomes that enter these fields form long tube-like appendages that can pinch-off into smaller liposomes. This proposed mechanism is consistent with colloidal theory and the observed behavior of liposomes in shear fields.     

Selective gene therapy for prostate cancer cells using liposomes conjugated with IgM type monoclonal antibody against prostate-specific membrane antigen

Prostate cancer cells express prostate-specific membrane antigen (PSMA). We developed an IgM type monoclonal antibody against PSMA. The antibody was coupled to poly-L-lysine and thereafter this conjugate was mixed with cationic liposomes containing plasmid DNA. The antibody-liposome complex was tested whether it could deliver the gene of interest selectively to the PSMA positive cells. As assessed by beta-galactosidase reporter gene, the transfection efficiency was 13.2% with anti-PSMA-liposome complex as compared to 4% with control IgM liposome complex. In contrast, no such differences were observed in PSMA negative PC-3, DU145 and T24 cells. Furthermore, in the suicide gene therapy in vitro with thymidine kinase gene plus ganciclovir system, anti-PSMA liposome complex demonstrated a selective growth inhibitory effect on PSMA positive LNCaP cells but not on PSMA negative cell lines.     

蜂毒肽在磷脂膜上取向的高效液相色谱和质谱研究

利用脂质体模型系统研究了跨膜电位对蜂毒肽在磷脂磷上取向的影响,采用高效液相色谱与质谱技术相结合方法,分析了蜂毒肽与磷脂膜作用后的胰蛋白酶酶解产物,结果发现,当蜂毒肽分子与没有跨膜电位的脂质体结合后,它的所有酶切位点都能够酶有效切断,当蜂毒肽与带负向膜电全的脂质体结合后,其Ｎ端的一个酶切位点被封闭,从而说明跨膜电位造成了蜂毒肽在膜上的重瓣取向。     

Absorbance-based assay for membrane disruption by antimicrobial peptides and synthetic copolymers using pyrroloquinoline quinone-loaded liposomes

A simple homogeneous assay for the detection of membrane permeabilization by antimicrobial peptides and synthetic copolymers is described. Liposomes encapsulating pyrroloquinoline quinone (PQQ), the prosthetic group of the apoenzyme glucose dehydrogenase (GDH), are used to detect membrane permeabilization by the antimicrobial peptides MSI-594 and MSI-78 as well as various synthetic antimicrobial copolymers in an optical microwell assay. PQQ-loaded liposomes and the peptide or copolymer are added to wells of a 96-well microtiter plate. If the integrity of the liposome is compromised, the PQQ encapsulated in the liposomes is released and available for activating the apoenzyme. The release of PQQ catalyzes a color change in the presence of apo-GDH, glucose, and the redox dye 1,6-dichlorophenol indophenol (DCPIP) that can be evaluated through a visual color change. For more quantitative measurements, the absorbance change over a 30 min period was measured. The absorbance change is related to the activity and concentration for a given antimicrobial agent. Furthermore, by varying liposome compositions to include cholesterol, the potential toxicity of the peptide or polymer toward mammalian cells can be readily evaluated. The assay is simple and sensitive and will be useful for analyzing the membrane permeation/disruption properties of a host of antimicrobial peptides and synthetic polymers.