Interferon sensitive and insensitive MHC variants of a murine thymoma differentially resistant to methotrexate-containing antibody-directed liposomes and immunotoxin

We evaluated the ability of methotrexate-containing liposomes or a ricin alpha-chain immunotoxin, both associated with monoclonal antibodies specific for the major histocompatibility complex-encoded class I molecule H-2Kk, to kill cells of the murine k haplotype thymoma RDM4. Cells were incubated with liposomes or immunotoxin in the presence or absence of interferon-gamma, which is known to augment the expression of the target class I molecules. The great majority of cells were killed by either of these reagents. Two types of mutant cells were obtained: type 1 cells, selected by methotrexate-containing liposomes, failed to express sufficient target H-2k molecules to be killed by liposomes in the absence of interferon-gamma. In the presence of interferon-gamma, these cells increased expression of all H-2 class I molecules and could be killed by targeted liposomes. Type 2 cells were immunoselected from cloned type 1 cells by liposomes in the presence of interferon. These cells failed to respond to interferon with expression of the H-2Kk molecule, but continued to augment H-2Dk expression in response to interferon. A third variant (type 3) selected from the wild type population by an H-2Kk specific immunotoxin in the absence of interferon phenotypically resembled type 1 cells. Type 1 but not type 2 cells respond to interferon by augmented synthesis of H-2Kk specific mRNA. The results suggest that for interferon-sensitive cell surface molecules of tumor cells, use of interferon improves the efficacy of targeted chemotherapy, but does not prevent development of mutants lacking the target molecule.     

Endocytosis and de novo expression of major histocompatibility complex encoded class I molecules: kinetic and ultrastructural studies

The endocytic pathway and expression of the major histocompatibility complex encoded class I molecule H-2Kk was investigated in murine fibroblasts. Internalization of H-2K molecules did not occur constitutively. Endocytosis of the molecules was induced by addition of multivalent ligands such as rabbit anti-mouse immunoglobulin serum or protein A-bearing liposomes to cells pretreated with anti-H-2Kk antibodies. The complete removal of H-2K molecules took about 5 h at 37 degrees C and was not inhibited by the lysosomotropic agent NH4Cl or the protein synthesis inhibitor cycloheximide. When targeted liposomes that contained carboxyfluorescein at a self-quenched concentration were directed against H-2K molecules, the cells became highly fluorescent after 30 min: a consequence of carboxyfluorescein release from the liposomes. This process was inhibited by NH4Cl but not by cycloheximide, suggesting internalization of H-2K molecules into acidic intracellular compartments. The endocytic pathway of liposomes directed against H-2K molecules and the subcellular compartments involved in this process were investigated with targeted liposomes containing horseradish peroxidase. By electron microscopy, the endocytic process was shown to start very rapidly (1-2 min) and involved uncoated cell surface invaginations. The cytoplasmic uncoated vesicles fused together into larger vacuoles containing concentrated liposomes and by 1 h, liposomes began to be destroyed in lysosomal compartments. Within 4 h, 90% of liposomes were lysed inside the cell. The fate of radiolabeled anti-H-2K antibody was also investigated. Degradation of the antibody occurred only when cross-linked with a second layer of antibody, beginning after 2 h and becoming more pronounced after 20 h of incubation. The original cell surface abundance of H-2K molecules was reestablished after 5 to 7 h. During this time neither NH4Cl nor cycloheximide had any effect on the cell surface expression of the molecule. However, after a second cycle of internalization, cells incubated with cycloheximide no longer expressed these molecules. These results suggested that H-2K molecules were not recycled back to the surface after internalization but were degraded in lysosomal compartments together with their ligand. Preexisting molecules, already present in intracellular pools, were expressed to replace them. By immunoprecipitation of metabolically labeled intracellular and surface H-2K molecules, we observed an intracellular pool of H-2K of about 70 to 80% of the total cellular H-2K.     

Endocytosis of liposomes bound to cell surface proteins measured by flow cytofluorometry.

A new technique for the quantification of cellular receptor-mediated endocytosis has been developed based on the analysis by flow cytometry of ligand-bearing liposomes containing the fluorochrome carboxyfluorescein. Carboxyfluorescein encapsulated at high concentrations in protein A-bearing liposomes is self-quenched. Binding and internalization of such liposomes by cells via antibodies directed towards membrane surface determinants results in the release of the liposome-encapsulated carboxyfluorescein into the cytoplasm causing an increase in cell-associated fluorescence. This increase can be quantified on a flow cytofluorometer.     

Dual parameter, quantitative cytofluorometric analysis of endogenous H-2Kk and foreign HLA class I molecules expressed at the surface of murine transformed L cells

By using a calibrated dual laser cell sorter and monoclonal antibodies directly conjugated to fluorescein and rhodamine and specific for H-2Kk and HLA class I antigens, quantitative cytofluorometric analysis was performed on individual HLA-A3 or -CW3 transformed mouse L cells (H-2k). More than 80% of these cells expressed both HLA class I and H-2Kk molecules. Their respective levels of expression were calculated: a mean of 4 X 10(5) HLA class I and 2.3 X 10(5) H-2Kk molecules per single cell. Quantitative comparison with control untransformed L cells and double fluorescence contour maps showed a positive correlation between the levels of expression of HLA class I and H-2Kk molecules suggesting that expression of foreign class I molecules did not occur at the expense of the endogenous H-2k product.     

Endocytosis and recycling of MHC-encoded class II molecules by mouse B lymphocytes

The movements of mouse MHC-encoded class II (H-2E) and class I (H-2K), transferrin receptor and surface Ig molecules of B lymphocytes were studied using radiolabeled mAb and electron microscopy. A total of 10 to 20% of antibodies specific for H-2E molecules were gradually internalized with a t 1/2 of 15 min, reaching a plateau after 30 min at 37 degrees C. Equivalent results were obtained either with the whole antibody or Fab' fragments, suggesting that the internalization of class II molecules was spontaneous. Similar results were obtained with antibodies specific for the transferrin receptor, of which 50% were internalized with t 1/2 of 5 min, reaching a plateau after 30 min. In contrast to antibodies specific for H-2E molecules and the transferrin receptor, antibodies specific for H-2K were not internalized. Reappearance of internalized H-2E-specific antibodies at the cell surface was observed at 37 degrees C. When compared to antibodies specific for surface Ig, degradation of antibodies specific for H-2E molecules was limited even after 5 h incubation. Neither ammonium chloride nor cycloheximide inhibited internalization and recycling. Electron microscopy showed that internalization of H-2E molecules occurred via coated pits/coated vesicles. These results indicate that class II molecules are spontaneously internalized and recycled by B lymphocytes.     

Preparation and Characterization of Ligand-Modified Labelled Liposomes for Solid Phase Immunoassays

Abstract

Small unilamellar vesicles conjugated with an enzyme label and with specific ligands for biological molecules may prove to be useful as signal enhancement vehicles in the development of enzyme-linked immunoadsorbent assays and other detection applications. Bifunctional vesicles have been prepared by covalently attaching horseradish peroxidase (HRP) and monoclonal antibodies to the outside of the lipid bilayer. The reaction conditions were optimized to obtain 7-12 antibody molecules and 100-200 HRP molecules per vesicle. The enzyme retained 70-80% of its specific activity after immobilization with no apparent change in vesicle stability. These bifunctional vesicles were used in a noncompetitive immunoassay for D-Dimer, a fibrin dimer formed at the early stages of thrombogenesis. The assay results using vesicles led to a detection limit for D-Dimer in human plasma which was five times lower than what was achieved using a conventional enzyme-antibody conjugate assay. HRP labelled (bifunctional) liposomes can also be used in competitive assays for the detection of small ligands in bulk solution. HRP and biotin-conjugated vesicles were prepared and used in competitive assays for biotin in free solution. The lowest detection limit for biotin using vesicles as the signal generation mechanism was found to be a factor of 10 lower than what could be observed with a traditional biotin-HRP conjugate. A model has been developed for the competition between a small ligand in solution and a large ligand-conjugated vesicle for binding sites on a solid surface.     

Quantitative Analysis of the Lamellarity of Giant Liposomes Prepared by the Inverted Emulsion Method

The inverted emulsion method is used to prepare giant liposomes by pushing water-in-oil droplets through the oil/water interface into an aqueous medium. Due to the high encapsulation efficiency of proteins under physiological conditions and the simplicity of the protocol, it has been widely used to prepare various cell models. However, the lamellarity of liposomes prepared by this method has not been evaluated quantitatively. Here, we prepared liposomes that were partially stained with a fluorescent dye, and analyzed their fluorescence intensity under an epifluorescence microscope. The fluorescence intensities of the membranes of individual liposomes were plotted against their diameter. The plots showed discrete distributions, which were classified into several groups. The group with the lowest fluorescence intensity was determined to be unilamellar by monitoring the exchangeability of the inner and the outer solutions of the liposomes in the presence of the pore-forming toxin α-hemolysin. Increasing the lipid concentration dissolved in oil increased the number of liposomes ∼100 times. However, almost all the liposomes were unilamellar even at saturating lipid concentrations. We also investigated the effects of lipid composition and liposome content, such as highly concentrated actin filaments and Xenopus egg extracts, on the lamellarity of the liposomes. Remarkably, over 90% of the liposomes were unilamellar under all conditions examined. We conclude that the inverted emulsion method can be used to efficiently prepare giant unilamellar liposomes and is useful for designing cell models.     

Direct involvement of surface IA/E molecules during B cell maturation using an antigen-specific B cell clone

TP67.14 is a subclone of a resulting B cell hybridoma established by somatic hybridization between splenic B cells of A/J mice immunized with TNP-LPS and 2.52 M, a HAT medium-sensitive mutant of a B cell line; it expresses IgM, B220, IAk, and IEk on the cell membrane and also possesses a receptor molecule for TNP on its surface derived from TNP-reactive B cells of A/J mice used for cell fusion. As shown previously, TP67.14 could be induced to generate a significant amount of anti-TNP antibodies when treated with TNP-conjugated protein such as TNP-BSA and TNP-keyhole limpet hemocyanin without T cell help as well as LPS. Our study was undertaken to investigate direct involvement of surface MHC class II molecules on B cells during B cell maturation by analysis with this Ag-specific B cell clone. The data demonstrate that mAb against IAk and IEk molecules, but not IAd and H-2k, markedly inhibited the differentiative effects of LPS on TP67.14. In contrast, both antibodies specifically augmented the secretion of anti-TNP antibodies by TP67.14 treated with TNP-BSA, although these antibodies alone failed to induce the generation of anti-TNP antibodies. Interestingly, TP67.14 significantly differentiated into anti-TNP antibody secreting cells when incubated with TNP-conjugated monoclonal anti-IAk or anti-IEk antibodies alone; this differentiative effect was much greater than that of TNP-conjugated anti-IAd mAb or purified mouse IgG under the same conditions. Our result suggests that surface IA/E molecules on B cells may be directly involved in a transductional signal for B cell maturation mediated by the cross-linkage of receptor molecules on B cells with Ag.     

Antibody targeted liposomes containing poly(rI).poly(rC) exert a specific antiviral and toxic effect on cells primed with interferons alpha/beta or gamma

Double-stranded RNA can stimulate interferon production and mediate an antiproliferative effect on certain cell types. We evaluated the possibility of specifically targeting to cells in vitro the RNA duplex poly(rI).poly(rC) in pharmacologically active form after its encapsulation in small, unilamellar liposomes, to which was covalently coupled protein A. These liposomes became bound to and were endocytosed by murine L929 cells in the presence of protein A-binding monoclonal antibodies specific for an expressed cell surface protein, the H-2K molecule. When L929 cells were preincubated in the presence of low doses of interferon alpha/beta or gamma, they could be activated to produce interferon following exposure to either free poly(rI).poly(rC), or specifically bound liposomes poly(rI).poly(rC), but not the same liposomes in the presence of non-cell binding control antibodies. Specifically bound liposome-encapsulated poly(rI).poly(rC) was toxic to L929 cells at dose levels at least three logs lower than free poly(rI).poly(rC). This toxicity was also dependent on pre-treatment with interferon. These results indicate that liposome-encapsulated poly(rI).poly(rC) can survive endocytosis and can be released in active form to specific cell populations, at concentrations much lower than that required for pharmacologic effects of the same molecule in free form. They suggest that introduction into cells of other nucleic acids might benefit from the antibody-targeted liposome technology described here.     

Fluorochrome staining of multilamellar liposomes.

Multilamellar liposomes can be stained with such fluorochromes as acridine orange, eosin Y, neutral red, and thiazine red. The liposomes are brought into a 1% solution of the fluorochrome; 5-10 minutes later they are centrifuged and washed by resuspending in water or phosphate buffered saline three times. The last pellet is resuspended and a drop studied with the fluorescence microscope (1000 x magnification). The fluorochrome is seen to be accumulated in the liposomal membranes. Acridine orange could also be trapped in the aqueous compartments of the liposomes but the trapped fluorochrome was gradually lost from the liposomes. Part of the fluorochrome, however, remained associated with the liposomal membranes for a long time. Additional experiments justify the conclusion that an equilibrium is maintained between fluorochromes in the aqueous and lipid phases.     

Quantitative Analysis of the Lamellarity of Giant Liposomes Prepared by the Inverted Emulsion Method

The inverted emulsion method is used to prepare giant liposomes by pushing water-in-oil droplets through the oil/water interface into an aqueous medium. Due to the high encapsulation efficiency of proteins under physiological conditions and the simplicity of the protocol, it has been widely used to prepare various cell models. However, the lamellarity of liposomes prepared by this method has not been evaluated quantitatively. Here, we prepared liposomes that were partially stained with a fluorescent dye, and analyzed their fluorescence intensity under an epifluorescence microscope. The fluorescence intensities of the membranes of individual liposomes were plotted against their diameter. The plots showed discrete distributions, which were classified into several groups. The group with the lowest fluorescence intensity was determined to be unilamellar by monitoring the exchangeability of the inner and the outer solutions of the liposomes in the presence of the pore-forming toxin α-hemolysin. Increasing the lipid concentration dissolved in oil increased the number of liposomes ∼100 times. However, almost all the liposomes were unilamellar even at saturating lipid concentrations. We also investigated the effects of lipid composition and liposome content, such as highly concentrated actin filaments and Xenopus egg extracts, on the lamellarity of the liposomes. Remarkably, over 90% of the liposomes were unilamellar under all conditions examined. We conclude that the inverted emulsion method can be used to efficiently prepare giant unilamellar liposomes and is useful for designing cell models.     

Preparation of giant liposomes in physiological conditions and their characterization under an optical microscope.

Unilamellar liposomes with diameters of 25-100 microns were prepared in various physiological salt solutions, e.g., 100 mM KCl plus 1 mM CaCl2. Successful preparation of the giant liposomes at high ionic strengths required the inclusion of 10-20% of a charged lipid, such as phosphatidylglycerol, phosphatidylserine, phosphatidic acid, or cardiolipin, in phosphatidylcholine or phosphatidylethanolamine. Three criteria were employed to identify unilamellar liposomes, yielding consistent results. Under a phase-contrast microscope those liposomes that showed the thinnest contour and had a vigorously undulating membrane were judged unilamellar. When liposomes were stained with the lipophilic fluorescent dye octadecyl rhodamine B, fluorescence intensities of the membrane of individual liposomes were integer multiples (up to four) of the lowest ones, the least fluorescent liposomes being those also judged unilamellar in the phase-contrast image. Micropipette aspiration test showed that the liposomes judged unilamellar in phase and fluorescence images had an area elastic modulus of approximately 160 dyn/cm, in agreement with literature values. The giant liposomes were stable and retained a concentration gradient of K+ across the membrane, as evidenced in fluorescence images of the K(+)-indicator PBFI encapsulated in the liposomes. Ionophore-induced K+ transport and associated volume change were observed in individual liposomes.     

Fluorochrome Staining of Multilamellar Liposomes

Multilamellar liposomes can be stained with such fluorochromes as acridine orange, eosin Y, neutral red, and thiazine red. The liposomes are brought into a 1% solution of the fluorochrome; 5-10 minutes later they are centrifuged and washed by resuspending in water or phosphate buffered saline three times. The last pellet is resuspended and a drop studied with the fluorescence microscope (1000 × magnification). The fluorochrome is seen to be accumulated in the liposomal membranes.

Acridine orange could also be trapped in the aqueous compartments of the liposomes but the trapped fluorochrome was gradually lost from the liposomes. Part of the fluorochrome, however, remained associated with the liposomal membranes for a long time.

Additional experiments justify the conclusion that an equilibrium is maintained between fluorochromes in the aqueous and lipid phases.     

Endocytosis of MHC molecules by B cell-B lymphoma and B cell-T lymphoma hybrids

Different cells and different cell surface determinants of the same cells take up liposomes, bound to them via monoclonal antibodies, with variable efficiency. We have previously reported that T and B lymphocytes differ in the extent to which they take up liposomes bound to MHC class I molecules; T cells endocytose class I molecules rapidly, but B cells endocytose class I molecules much less efficiently, although their endocytosis of class II molecules is rapid. An approach toward understanding the molecular basis for this difference was made by evaluating the internalization patterns of somatic cell hybrids of B and T cells. Hybrid cells were constructed between LPS-stimulated purified B cell blasts from C57BL/6 mice (H-2b) and the HAT-sensitive AKR T lymphoma BW 5147 (H-2k). Hybrids between the BALB/c B lymphoma M12.4.1 (H-2d) and B cell LPS blasts from B10.BR (H-2k) mice were also evaluated. In all cases, for hybrid tumor cells, liposomes that were bound to class I molecules encoded by genes from the B cell donor were endocytosed as efficiently as liposomes bound to the class I molecules of the recipient lymphoid cell. T cell tumors efficiently internalized their own class I molecules and those donated by B cells; B cell tumors internalized liposomes that were bound to their own and the donor B cell class I molecules poorly. Thus, our results suggest that the internalization of an MHC molecule is not an intrinsic property of the molecule, but rather of the cell in which it is found.     

Detection of the plant pathogenic bacterium Xanthomonas campestris pv. Campestris in seed extracts of Brassica sp. Applying fluorescent antibodies and flow cytometry

BACKGROUND: Xanthomonas campestris pv. campestris (Xcc) is a seed-transmitted plant pathogenic bacterium that causes black rot of crucifers. Seed lots and plants are screened for contamination with this pathogen using plating or serological assays. These methods, however, are time consuming and not very sensitive, respectively. Therefore, flow cytometry (FCM) was evaluated as a tool for the rapid detection and quantification of Xcc cells labeled with a mixture of specific fluorescein isothicyanate (FITC)-monoclonal antibodies (mAb) in pure culture, in mixed cultures of Xcc with either the common saprophyte Pseudomonas fluorescens (Psf) or a nonpathogenic X. campestris isolate (Xc), and in crude seed extracts. METHODS: The mAb 18G12, conjugated with FITC, was tested at dilutions of 1:50, 1:100, 1:200, and 1:400. For mixed suspensions of Xcc and Psf, mAb 18G12 was used at a dilution of 1:100. The combination of mAbs 18G12, 2F4, and 20H6, all conjugated with FITC, was used at a dilution of 1:100 for the detection and quantification of Xcc cells in mixed suspensions containing Xcc and Xc and in crude seed extracts. The analyses were performed with a Coulter EPICS XL-MCL flow cytometer, at low flow rate during 2 min. RESULTS: Using FCM, Xcc cells labeled with FITC-conjugated mAbs (18G12, 2F4, and 20H6) were detected and quantified rapidly at low numbers, i.e., 10(3) colony-forming units per milliliter in pure and in mixed cultures with Psf. The presence of the nonpathogenic Xc in the seed extracts did not interfere with the FCM results. Xcc cells were distinguished from the cells of other organisms and from small particles present in the seed extract based on the high-intensity fluorescence of the labeled cells. CONCLUSION: The application of FCM in combination with FITC-conjugated mAbs appears to be a promising technique for the detection and quantification of Xcc cells in seed extracts of crucifers.     

The development and application of protein-liposome conjugation techniques

Numerous techniques have been developed over the past 10 years for the conjugation of proteins to liposomes. Early procedures involved coupling with reagents such as glutaraldehyde or EDCI. Subsequently, more sophisticated approaches involving selective bifunctional coupling agents have been developed. These later procedures are also much more efficient for coupling in aqueous media. The techniques of coupling have become more rigorous because investigators have recognized the inherent problems of producing, purifying and characterizing protein conjugated liposomes.

Protein-liposome coupling techniques were developed mainly for targeted drug delivery. The attachment of specific antibodies to the surface of the liposomes makes them able to bind to cells and to subsequently be internalised by the cells. Protein conjugated liposomes have also been used for various immunochemical and diagnostic purposes. These include the binding of labelled liposomes to cells and the agglutination of cells or latex particles by protein conjugated liposomes.     

Enhanced Gene Delivery and Expression in Human Hepatocellular Carcinoma Cells by Cationic Immunoliposomes

Abstract

A targeted vector allowing enhanced gene transfer to human hepatocellular carcinoma (HCC¹) cells in vitro was developed using cationic liposomes covalently conjugated with the mAb AF-20. This high affinity antibody recognizes a rapidly internalized 180 kDa cell surface glycoprotein which is abundantly expressed on the surface of human HCC and other cancer cells. Quantitative binding analysis of liposomes with target cells by flow cytometry showed specific association of mAb-targeted liposomes with human HCC cells. Using mAb-targeted cationic liposomes containing 20% DOTAP, in the presence or absence of serum, gene expression in HuH-7 cells was enhanced up to 40-fold as compared to liposomes conjugated with an isotype-matched non-relevant control antibody. Transfection specificity was not observed in a control cell line that does not express the antigen recognized by mAb AF-20. This study demonstrates that cationic liposome formulations can be targeted with monoclonal antibodies (mAbs) to enhance specific in vitro gene delivery and expression in the presence or absence of serum.     

Dual parameter, quantitative cytofluorometric analysis of endogenous H-2K and foreign HLA class I molecules expressed at the surface of murine transformed L cells

By using a calibrated dual laser cell sorter and monoclonal antibodies directly conjugated to fluorescein and rhodamine and specific for H-2K^k and HLA class I antigens, quantitative cytofluorometric analysis was performed on individual HLA-A3 or -CW3 transformed mouse L cells (H-2^k). More than 80% of these cells expressed both HLA class I and H-2K^k molecules. Their respective levels of expression were calculated: a mean of 4 × 10⁵ HLA class I and 2.3 × 10⁵ H-2K^k molecules per single cell. Quantitative comparison with control untransformed L cells and double fluorescence contour maps showed a positive correlation between the levels of expression of HLA class I and H-2K^k molecules suggesting that expression of foreign class I molecules did not occur at the expense of the endogenous H-2^k product.     

Relationships between private and public H-2 specificities on the cell surface

Differential redistribution was used to investigate relationships between private specificity H-2.4 and public specificity H-2.28, in the product of aD region allele of theH-2 complex. Monospecific anti-H-2 antisera and fluorochrome conjugated antimouse Ig antibodies were used to induce redistribution of H-2 antigens on the surface of peripheral T lymphocytes fromH-2 ^a andH-2 ^d mice. Results showed that redistribution of specificity H-2.4 into patches and caps did not induce concomittant redistribution of specificity H-2.28, which remain diffusely scattered on the cell surface outside the caps of H-2.4. Redistribution of H-2.28 induced redistribution of H-2.4, which was no longer detectable outside the caps of H-2.28. These data indicate that (a) at least some of the H-2.28 sites are expressed on polypeptide chains independent from those carrying H-2.4 and (b) other H-2.28 sites may be linked to molecules carrying H-2.4. Since, onH-2 ^a cells, both specificities are products of the D region of theH-2 gene complex, our results suggest that there are at least two genes in theD region.     

Increased circulatory half-life of liposomes after conjunction with dextran

Dextran was covalently coupled to neutral unilamellar liposomes. Dextran conjugated liposomes were cleared from the circulation at a much slower rate than unconjugated liposomes. The uptake of dextran conjugated liposomes by liver and spleen was also decreased. The amount of dextran on the surface of liposomes was found to be a determining factor for their stability in circulation. Dextran conjugated liposomes therefore may be a more effective way of controlled drug release