Complement activation following first exposure to pegylated liposomal doxorubicin (Doxil): possible role in hypersensitivity reactions.

BACKGROUND: Pegylated liposomal doxorubicin (Doxil) has been reported to cause immediate hypersensitivity reactions (HSRs) that cannot be explained as IgE-mediated (type I) allergy. Previous in vitro and animal studies indicated that activation of the complement (C) system might play a causal role in the process, a proposal that has not been tested in humans to date. PATIENTS AND METHODS: Patients with solid tumors (n = 29) treated for the first time with Doxil were evaluated for HSRs and concurrent C activation. HSRs were classified from mild to severe, while C activation was estimated by serial measurement of plasma C terminal complex (SC5b-9) levels. Increases in SC5b-9 were compared in patients with or without reactions, and were correlated with Doxil dose rate. RESULTS: Moderate to severe HSRs occurred in 45% of patients. Plasma SC5b-9 at 10 min after infusion was significantly elevated in 92% of reactor patients versus 56% in the non-reactor group, and the rise was greater in reactors than in non-reactors. We found significant association between C activation and HSRs, both showing direct correlation with the initial Doxil dose rate. CONCLUSIONS: C activation may play a key role in HSRs to Doxil. However, low-level C activation does not necessarily entail clinical symptoms, highlighting the probable involvement of further, as yet unidentified, amplification factors.

Role of complement activation in hypersensitivity reactions to doxil and hynic PEG liposomes: experimental and clinical studies.

Pegylated liposomal doxorubicin (Doxil) and 99mTc-HYNIC PEG liposomes (HPL) were reported earlier to cause hypersensitivity reactions (HSRs) in a substantial percentage of patients treated i.v. with these formulations. Here we report that (1) Doxil, HPL, pegylated phosphatidylethanolamine (PEG-PE)-containing empty liposomes matched with Doxil and HPL in size and lipid composition, and phosphatidylglycerol (PG)-containing negatively charged vesicles were potent C activators in human serum in vitro, whereas small neutral liposomes caused no C activation. (2) Doxil and other size-matched PEG-PE and/or PG-containing liposomes also caused massive cardiopulmonary distress with anaphylactoid shock in pigs via C activation, whereas equivalent neutral liposomes caused no hemodynamic changes. (3) A clinical study showed more frequent and greater C activation in patients displaying HSR than in non-reactive patients. These data suggest that liposome-induced HSRs in susceptible individuals may be due to C activation, which, in turn, is due to the presence of negatively charged PEG-PE in these vesicles.

Formation of complement-activating particles in aqueous solutions of Taxol: possible role in hypersensitivity reactions.

We reported earlier that the anticancer drug paclitaxel (Taxol) activated the complement (C) system in human serum in vitro, raising the possibility that C activation might play a role in the ill-understood hypersensitivity reactions (HSRs) to this drug [J. Natl. Cancer Inst. 90 (1998) 300]. In pursuing the mechanism of C activation by Taxol, the present study provided evidence that dilution of the injection concentrate in aqueous solvents led to the formation of micelles and needle-like structures, both of which caused C activation in vitro. Micelles were formed mainly from Cremophor EL (CrEL), the nonionic emulsifier vehicle of paclitaxel, whose level in Taxol infusion exceeded its critical micelle concentration by at least 400-fold. CrEL micelles were shown by quasi-elastic light scattering and cryo-transmission electron microscopy (cryo-TEM) to be spherical with diameters in the 8-22 nm range; however, de novo formation of 50-300 nm microdroplets following incubation with human plasma suggested further fundamental structural transformation in blood. The needle-like structures extended to the multimicron range and were shown by electron diffraction to be crystalline paclitaxel. Taxol-induced C activation was manifested in varying rises of serum C3a-desarg, iC3b and SC5b-9. The causal role of CrEL micelles in C activation was demonstrated by the fact that filtration of aqueous solutions of Taxol or pure CrEL via 30-kDa cutoff filters eliminated, while the filter retentate restored C activation. C activation by Taxol was also inhibited by 10 mg/ml human immunoglobulin (IVIG). If proven clinically, HSRs to Taxol may represent a hitherto vaguely classified adverse drug reaction recently called C activation-related pseudoallergy (CARPA) [Circulation 99 (1999) 2302].

Transcutaneous immunization: T cell responses and boosting of existing immunity.

Transcutaneous immunization (TCI) is a novel immunization strategy by which antigen and adjuvant are applied topically to intact, hydrated skin to induce potent antibody and cell-mediated immune responses specific for both the antigen and the adjuvant. Using tetanus toxoid as a model antigen, we examined the T cell response to tetanus toxoid after topical immunization with a variety of adjuvants. TCI readily induced systemic antigen specific T cell responses with a mixed Th1/Th2 phenotype but with a Th2 bias. We also investigated whether priming by the intramuscular route, which is known to induce T cell memory, could be followed by a boosting immunization on the skin to induce secondary responses. TCI could augment existing immunity, but interestingly, this strategy induced potent responses only if the antibody titer was low at the time of TCI boosting. These and previous observations suggest that TCI follows known immunological principles that govern other routes of vaccine delivery. Furthermore, booster immunization using tetanus toxoid may provide a useful model for further development of important patch and formulation concepts for TCI, and act as an early candidate for validating product feasibility of TCI in humans.

Transcutaneous immunization: a human vaccine delivery strategy using a patch.

Transcutaneous immunization, a topical vaccine application, combines the advantages of needle-free delivery while targeting the immunologically rich milieu of the skin. In animal studies, this simple technique induces robust systemic and mucosal antibodies against vaccine antigens. Here, we demonstrate safe application of a patch containing heat-labile enterotoxin (LT, derived from Escherichia coli) to humans, resulting in robust LT-antibody responses. These findings indicate that TCI is feasible for human immunization, and suggest that TCI may enhance efficacy as well as improve vaccine delivery.

Induction and detection of antibodies to squalene.

An enzyme-linked immunosorbent assay (ELISA) utilizing antigen coated on hydrophobic polyvinyldiene fluoride (PVDF) membranes is described for detecting antibodies that bind to squalene (SQE). Because of the prior lack of availability of validated antibodies to SQE, positive controls for the assay were made by immunization with formulations containing SQE to create monoclonal antibodies (mAbs) that reacted with SQE. Among eight immunogens tested, only two induced detectable murine antibodies to SQE: liposomes containing dimyristoyl phosphatidylcholine, dimyristoyl phosphatidylglycerol, 71% SQE, and lipid A [L(71% SQE+LA)], and, to a much lesser extent, an oil-in-water emulsion containing SQE, Tween 80, Span 85, and lipid A. In each case, lipid A served as an adjuvant, but neither SQE alone, SQE mixed with lipid A, liposomes containing 43% SQE and lipid A, nor several other emulsions containing both SQE and lipid A, induced antibodies that reacted with SQE. Monoclonal antibodies produced after immunizing mice with [L(71% SQE+LA)] served as positive controls for developing the ELISA. Monoclonal antibodies were produced that either recognized SQE alone but did not recognize squalane (SQA, the hydrogenated form of SQE), or that recognized both SQE and SQA. As found previously with other liposomal lipid antigens, liposomes containing lipid A also induced antibodies that reacted with the liposomal phospholipids. However, mAbs were also identified that reacted with SQE on PVDF membranes, but did not recognize either SQA or liposomal phospholipid. The polyclonal antiserum produced by immunizing mice with [L(71% SQE+LA)] therefore contained a mixed population of antibody specificities and, as expected, the ELISA of polyclonal antiserum with PVDF membranes detected antibodies both to SQE and SQA. We conclude that SQE is a weak antigen, but that antibodies that specifically bind to SQE can be readily induced by immunization with [L(71% SQE+LA)] and detected by ELISA with PVDF membranes coated with SQE.

Proteasome inhibitors block the entry of liposome-encapsulated antigens into the classical MHC class I pathway.

Liposome-encapsulated conalbumin (L(conalbumin)) is an antigen that is efficiently phagocytosed by bone marrow-derived macrophages and presented to effector cells as part of the major histocompatibility complex (MHC) class I complex. In this report, we show that the conalbumin component of L(conalbumin) is degraded to small peptide fragments and translocated to the area of the Golgi. Golgi localization is confirmed by co-localization of L(Texas red-conalbumin) (L(TR-conalbumin))with both NBD-ceramide, a lipid Golgi marker, and green fluorescent protein (GFP)-galactosyl transferase, a Golgi resident enzyme. Incubation of the cells with brefeldin A disrupts the Golgi and disperses the TR-conalbumin. Furthermore, when macrophages were incubated with another liposome-encapsulated antigen, L(ovalbumin), ovalbumin peptides were observed in the Golgi area and MHC class I-peptide complexes could be detected on the cell surface by both immunofluorescence microscopy and flow cytometry. The Golgi localization observed in vitro in cultured macrophages is mirrored by the in vivo uptake and Golgi localization of fluorescent L(conalbumin) in macrophages isolated from the spleen of a mouse injected with L(TR-conalbumin). The accumulation of peptide fragments in the Golgi is inhibited by the addition of the proteasome inhibitors, lactacystin and MG-132, demonstrating the role of the proteasome in this activity. In addition, when macrophages or a macrophage-derived cell line, are incubated with liposome-enccapsulated antigens and used as target cells in a cytotoxic T-cell (CTL) assay, the CTLs recognize the processed peptide-MHC complexes and kill the cells. In contrast, specific lysis of target cells by CTLs is inhibited when the target cells are first incubated with lactacystin. These results suggest that uptake and processing of L(antigen) follows the classical MHC class I pathway.

Liposome-induced pulmonary hypertension: properties and mechanism of a complement-mediated pseudoallergic reaction.

Intravenous injection of liposomes can cause significant pulmonary hypertension in pigs, a vasoconstrictive response that provides a sensitive model for the cardiopulmonary distress in humans caused by some liposomal drugs. The reaction was recently shown to be a manifestation of "complement activation-related pseudoallergy" (CARPA; Szebeni J, Fontana JL, Wassef NM, Mongan PD, Morse DS, Dobbins DE, Stahl GL, Bünger R, and Alving CR. Circulation 99: 2302-2309, 1999). In the present study we demonstrate that the composition, size, and administration method of liposomes have significant influence on pulmonary vasoactivity, which varied between instantaneously lethal (following bolus injection of 5 mg lipid) to nondetectable (despite infusion of a 2,000-fold higher dose). Experimental conditions augmenting the pulmonary hypertensive response included the presence of dimyristoyl phosphatidylglycerol, 71 mol% cholesterol, distearoyl phosphatidylcholine, and hemoglobin in liposomes, increased vesicle size and polydispersity, and bolus injection vs. slow infusion. The vasoactivity of large multilamellar liposomes was reproduced with human C3a, C5a, and xenoreactive immunoglobulins, and it correlated with the complement activating and natural antibody binding potential of vesicles. Unilamellar, monodisperse liposomes with 0.19 +/- 0.10 microm mean diameter had no significant vasoactivity. These data indicate that liposome-induced pulmonary hypertension in pigs is multifactorial, it is due to natural antibody-triggered classic pathway complement activation and it can be prevented by appropriate tailoring of the structure and administration method of vesicles.

Transcutaneous immunization with bacterial ADP-ribosylating exotoxins, subunits, and unrelated adjuvants.

We have recently described a needle-free method of vaccination, transcutaneous immunization, consisting of the topical application of vaccine antigens to intact skin. While most proteins themselves are poor immunogens on the skin, we have shown that the addition of cholera toxin (CT), a mucosal adjuvant, results in cellular and humoral immune responses to the adjuvant and coadministered antigens. The present study explores the breadth of adjuvants that have activity on the skin, using diphtheria toxoid (DTx) and tetanus toxoid as model antigens. Heat-labile enterotoxin (LT) displayed adjuvant properties similar to those of CT when used on the skin and induced protective immune responses against tetanus toxin challenge when applied topically at doses as low as 1 microg. Interestingly, enterotoxin derivatives LTR192G, LTK63, and LTR72 and the recombinant CT B subunit also exhibited adjuvant properties on the skin. Consistent with the latter finding, non-ADP-ribosylating exotoxins, including an oligonucleotide DNA sequence, as well as several cytokines (interleukin-1beta [IL-1beta] fragment, IL-2, IL-12, and tumor necrosis factor alpha) and lipopolysaccharide also elicited detectable anti-DTx immunoglobulin G titers in the immunized mice. These results indicate that enhancement of the immune response to topical immunization is not restricted to CT or the ADP-ribosylating exotoxins as adjuvants. This study also reinforces earlier findings that addition of an adjuvant is important for the induction of robust immune responses to vaccine antigens delivered by topical application.

Delivery of lipids and liposomal proteins to the cytoplasm and Golgi of antigen-presenting cells. mangala.rao@na.amedd.army.mil.

Liposomes have the well-known ability to channel protein and peptide antigens into the MHC class II pathway of phagocytic antigen-presenting cells (APCs) and thereby enhance the induction of antibodies and antigen-specific T cell proliferative responses. Liposomes also serve as an efficient delivery system for entry of exogenous protein and peptide antigens into the MHC class I pathway and thus are very efficient inducers of cytotoxic T cell responses. Soluble antigens that are rendered particulate by encapsulation in liposomes are localized both in vacuoles and in the cytoplasm of bone marrow-derived macrophages. Utilizing fluorophore-labeled proteins encapsulated in liposomes we have addressed the question of how liposomal antigens enter the MHC class I pathway. After phagocytosis of the liposomes, the fluorescent liposomal protein and liposomal lipids enter the cytoplasm where they are processed by the proteasome complex. The processed liposomal protein is then transported via the TAP complex into the endoplasmic reticulum and the Golgi complex. Both the liposomal lipids and the liposomal proteins appear to follow the same intracellular route and they are processed as a protein-lipid unit. In the absence of a protein antigen (empty liposomes), there is no organelle-specific localization of the liposomal lipids. In contrast, when a protein is encapsulated in these liposomes, the distribution of the liposomal lipids is dramatically affected and the liposomal lipids localize to the trans-Golgi area. Localization of the protein in the trans-Golgi area requires liposomal lipids. Similarly, for the localization of liposomal lipids in the trans-Golgi area, there is an obligatory requirement for protein. Therefore, the intracellular trafficking patterns of liposomal lipids and liposomal protein are reciprocally regulated. Presence of both liposomal lipids and liposomal protein in the trans-Golgi therefore facilitates the entry of liposomal antigens into the MHC class I pathway. It is also possible that liposomal lipids are presented to T cells via the recently described CD1 pathway for lipid antigens. Because liposome-formulated vaccines have the potential to stimulate antibody as well as cellular immune responses to protein and lipid components, this approach could prove to be extremely useful in designing vaccine strategies.

Oil-in-water liposomal emulsions: characterization and potential use in vaccine delivery.

Emulsification of mineral oil by phospholipids donated by liposomes composed of dimyristoyl phosphatidylcholine, dimyristoyl phosphatidylglycerol, cholesterol, and lipid A by extrusion resulted in the formation of oil-in-water liposomal emulsions containing a substantial number of intact liposomes. Increasing the proportion of liposomes from 25 mM to 150 mM phospholipid and increasing the oil content from 2.5% (v/v) to 42.5% (v/v) changed the flow characteristics of the emulsions from fluid liquid-like to viscous. Likewise, the degree of stability of the emulsions was liposomal phospholipid concentration-dependent, ranging from partial emulsification in the range 25-100 mM to complete stabilization in the range 125-150 mM. Despite some loss of liposome integrity, as evidenced by the release of liposomal trapped glucose, emulsification of liposomes containing encapsulated prostate-specific antigen (PSA) exhibited antigen-specific immunostimulation in mice. These results suggest that liposomes containing encapsulated antigen can serve as constituents for the formulation of oil-in-water vaccines.

Principles of transcutaneous immunization using cholera toxin as an adjuvant.

Transcutaneous immunization is a novel strategy for immunization employing topical application of antigen and adjuvant to the skin surface and resulting in detectable antigen/adjuvant specific IgG in plasma and mucosal secretions. In this study we show that transcutaneous immunization with cholera toxin (CT) as an adjuvant can be used in several inbred mouse strains with varying H-2 major histocompatibility complex genes (C57BL/6 (H-2(b)), BALB/c (H-2(d)), and C3H (H-2(k))). Although the primary anti-CT antibody responses reflected previously described MHC restriction patterns for this protein, the differences were overcome after two booster immunizations. Potent antibody responses against hen egg lysozyme and/or diphtheria toxoid were observed using CT as adjuvant. We also demonstrate that the unshaved dorsal or ventral surface of the ear can be effectively used for transcutaneous immunization and that gentle swabbing with alcohol increases the magnitude of the host immune response. Together these data further our understanding of the principles governing this new platform technology and support its integration into novel and existing human vaccine strategies.

Cytotoxic T lymphocytes to Ebola Zaire virus are induced in mice by immunization with liposomes containing lipid A.

An eight amino acid sequence (TELRTFSI) present in the carboxy terminal end (aa 577-584) of membrane-anchored GP, the major structural protein of Ebola virus, was identified as an H-2k-specific murine cytotoxic T cell epitope. Cytotoxic T lymphocytes (CTLs) to this epitope were induced by immunizing B10.BR mice intravenously with either irradiated Ebola virus or with irradiated Ebola virus encapsulated in liposomes containing lipid A. The CTL response induced by irradiated Ebola virus could not be sustained after the second round of in vitro stimulation of immune splenocytes with the peptide, unless the irradiated virus was encapsulated in liposomes containing lipid A. The identification of an Ebola GP-specific CTL epitope and the requirement of liposomal lipid A for CTL memory recall responses could prove to be a promising approach for developing a vaccine against Ebola virus infection.

Naturally occurring antibodies to cholesterol: a new theory of LDL cholesterol metabolism.

Although low-density lipoprotein (LDL) receptors regulate the disposition of two-thirds of circulating serum LDL cholesterol, non-LDL receptor mechanisms account for removal of one-third. Here, Carl Alving and Nabila Wassef propose that naturally occurring antibodies to cholesterol in normal human plasma also contribute to LDL cholesterol turnover by opsonizing LDL and other lipoproteins containing 'bad' cholesterol for removal by complement receptors.

Hemodynamic changes induced by liposomes and liposome-encapsulated hemoglobin in pigs: a model for pseudoallergic cardiopulmonary reactions to liposomes. Role of complement and inhibition by soluble CR1 and anti-C5a antibody.

BACKGROUND: Intravenous administration of some liposomal drugs can trigger immediate hypersensitivity reactions that include symptoms of cardiopulmonary distress. The mechanism underlying the cardiovascular changes has not been clarified. METHODS AND RESULTS: Anesthetized pigs (n=18) were injected intravenously with 5-mg boluses of large multilamellar liposomes, and the ensuing hemodynamic, hematologic, and laboratory changes were recorded. The significant (P<0.01) alterations included 79+/-9% (mean+/-SEM) rise in pulmonary arterial pressure, 30+/-7% decline in cardiac output, 11+/-2% increase in heart rate, 236+/-54% increase in pulmonary vascular resistance, 71+/-27% increase in systemic vascular resistance, and up to a 100-fold increase in plasma thromboxane B2. These changes peaked between 1 and 5 minutes after injection, subsided within 10 to 20 minutes, were lipid dose-dependent (ED50=4. 5+/-1.4 mg), and were quantitatively reproducible in the same animal several times over 7 hours. The liposome-induced rises of pulmonary arterial pressure showed close quantitative and temporal correlation with elevations of plasma thromboxane B2 and were inhibited by an anti-C5a monoclonal antibody (GS1), by sCR1, or by indomethacin. Liposomes caused C5a production in pig serum in vitro through classic pathway activation and bound IgG and IgM natural antibodies. Zymosan- and hemoglobin-containing liposomes and empty liposomes caused essentially identical pulmonary changes. CONCLUSIONS: The intense, nontachyphylactic, highly reproducible, complement-mediated pulmonary hypertensive effect of minute amounts of intravenous liposomes in pigs represents a unique, unexplored phenomenon in circulation physiology. The model provides highly sensitive detection and study of cardiopulmonary side effects of liposomal drugs and many other pharmaceutical products due to "complement activation-related pseudoallergy" (CARPA).

Complement-mediated acute effects of liposome-encapsulated hemoglobin.

Recent studies on liposome-encapsulated hemoglobin (LEH) have indicated that this potential blood substitute can activate the complement (C) system of rats, pigs and man. The reaction can involve both the classical and the alternative pathways, and is mediated, in part, by the binding of natural anti-lipid antibodies to the lipid membrane of liposomes. The significance of these discoveries lies in the fact that C activation appears to be the primary cause of the acute physiological, hematological and laboratory changes that have been observed previously in rats and pigs following the administration of LEH or liposomes, which changes include pulmonary vasoconstriction with decreased cardiac output. In light of the proposed use of LEH as an emergency blood substitute, the latter impairment of cardiopulmonary function may warrant particular circumspection as it could aggravate the clinical state of trauma patients who are prone to develop respiratory distress partly as a consequence of C activation by the injury. Our studies on rats and pigs suggest that the above acute side effects of LEH, including the cardiopulmonary distress, can be efficiently inhibited with soluble complement receptor type I, a specific inhibitor of C activation.

Transcutaneous immunization with bacterial ADP-ribosylating exotoxins as antigens and adjuvants.

Transcutaneous immunization (TCI) is a new technique that uses the application of vaccine antigens in a solution on the skin to induce potent antibody responses without systemic or local toxicity. We have previously shown that cholera toxin (CT), a potent adjuvant for oral and nasal immunization, can induce both serum and mucosal immunoglobulin G (IgG) and IgA and protect against toxin-mediated mucosal disease when administered by the transcutaneous route. Additionally, CT acts as an adjuvant for coadministered antigens such as tetanus and diphtheria toxoids when applied to the skin. CT, a member of the bacterial ADP-ribosylating exotoxin (bARE) family, is most potent as an adjuvant when the A-B subunits are present and functional. We now show that TCI induces secondary antibody responses to coadministered antigens as well as to CT in response to boosting immunizations. IgG antibodies to coadministered antigens were also found in the stools and lung washes of immunized mice, suggesting that TCI may target mucosal pathogens. Mice immunized by the transcutaneous route with tetanus fragment C and CT developed anti-tetanus toxoid antibodies and were protected against systemic tetanus toxin challenge. We also show that bAREs, similarly organized as A-B subunits, as well as the B subunit of CT alone, induced antibody responses to themselves when given via TCI. Thus, TCI appears to induce potent, protective immune responses to both systemic and mucosal challenge and offers significant potential practical advantages for vaccine delivery.

Trafficking of liposomal antigen to the trans-Golgi of murine macrophages requires both liposomal lipid and liposomal protein.

Major histocompatibility complex (MHC) class I molecules found on antigen-presenting cells present peptides derived from cytoplasmic proteins to T cells. In contrast, peptides from exogenous proteins are mostly presented by class II molecules. It has been well established that liposomes can serve as an efficient delivery system for entry of exogenous protein antigens into the MHC class I pathway. Our previous studies utilizing fluorophore-labeled proteins encapsulated in liposomes demonstrated that after phagocytosis of the liposomes by bone marrow-derived macrophages (BMs), the processed peptides were subsequently visualized in the trans-Golgi, while free conalbumin was excluded from the trans-Golgi area. In the present study, we investigated whether liposomal lipids follow the same intracellular route as the liposomal proteins after phagocytosis by BMs. Multilamellar liposomes with different lipid compositions that also contained fluorescent phospholipids (empty liposomes) were incubated with murine BMs. Our results indicate that although empty liposomes were avidly phagocytosed by macrophages, the fluorescent liposomal lipids did not localize to any particular area of the cell but were distributed throughout the cell. In contrast, when a protein was encapsulated in the liposomes, the liposomal lipids were no longer dispersed throughout the cell, but were concentrated and localized in the trans-Golgi area. Furthermore, when the liposomes contained a fluorescent-labeled protein, the fluorescent peptides also localized to the trans-Golgi. These results demonstrate that the combination of both liposomal lipids and liposomal protein is required for Golgi-specific targeting of liposomal antigens. Transport of both liposomal lipids and liposomal proteins to the Golgi complex, a major subcellular organelle in the passage of MHC class I molecules, might explain why antigens encapsulated in liposomes readily induce cytotoxic T lymphocytes.

Advances in vaccine delivery: transcutaneous immunisation.

Needle-free delivery of vaccines has become a global priority. Transcutaneous immunisation (TCI), topical application of vaccine antigens to the skin, can elicit systemic antibody and T-cell responses, suggesting that this new technique may provide a means for vaccination without needles. TCI requires the use of an adjuvant such as cholera toxin added to a vaccine antigen, such as diphtheria toxoid, to induce antibodies to diphtheria toxoid. The adjuvant and antigen are thought to target Langerhans cells, potent antigen-presenting cells found in the superficial layers of the skin. TCI appears to be a highly practical technique for delivery of vaccines that provides unique access to the immune system.