Emiliana Jelezarova

The Role of Complement Activation in Hypersensitivity to Pegylated Liposomal Doxorubicin (Doxil

Abstract Liposomal formulations of some drugs, most importantly pegylated liposomal doxorubicin (Doxil®), have been reported to cause immediate hypersensitivity reactions that cannot be explained with the conventional paradigm of IgE-mediated (type I) allergy. Here we present a rationale and experimental evidence for the concept that these reactions represent a novel type of drug-induced hypersensitivity that can be called complement (C) activation-related pseudoallergy (CARPA). The theoretical foundation includes the facts that 1) some liposomes have been known to activate C, 2) most of the clinical symptoms of liposome-induced reactions coincide with those caused by C activation by other activators, and 3) the C mechanism explains those manifestations which are atypical for type 1 reactions. The experimental evidence includes the observations that 1) Doxil caused massive C activation in a high ratio (4/10) of normal human sera, 2) high dose IgG attenuated Doxil-induced C activation in serum and prevented further C activation by amplification, and 3) intravenous injection of therapeutically relevant doses of Doxil in pigs caused significant pulmonary hypertension with consequent systemic hypotension and decline of cardiac output, which changes mimicked the cardiovascular manifestations of the human reaction and were shown to be triggered by C activation. As for the question how Doxil, a long-circulating “stealth” liposome formulation, avoids phagocytic uptake by macrophages despite its potential opsonization by C3b, we demonstrated efficient inactivation of Doxil-bound and free C3b to iC3b in human serum. Thus, it is unlikely that PEG would interfere with CD11b/CD18-mediated phagocytosis by inhibiting the formation of its main ligand, iC3b.

C3b2-IgG Complexes Retain Dimeric C3 Fragments at All Levels of Inactivation

C3b2-IgG complexes are formed during complement activation in serum by attachment of two C3b molecules (the proteolytically activated form of C3) to one IgG heavy chain (IgG HC) via ester bonds. Because of the presence of two C3b molecules, these complexes are very efficient activators of the alternative complement pathway. Likewise, dimeric C3b is known to enhance complement receptor 1-dependent phagocytosis, and dimeric C3d (the smallest thioester-containing fragment of C3) linked to a protein antigen facilitates CR2-dependent B-cell proliferation. Because the efficiency of all these interactions depends on the number of C3 fragments, we investigated whether C3b2-IgG complexes retained dimeric structure upon physiological inactivation. We used two-dimensional SDS-PAGE and Western blot to study the arrangement of the C3b molecules by analyzing the fragmentation pattern after cleavage of the ester bonds. Upon inactivation with factors H and I, a 185-kDa band was generated under reducing conditions. It released IgG HC and the 65-kDa fragment of C3b α′ chain after hydrolysis of the ester bonds with hydroxylamine. The two C3b molecules were not 65-kDa-to-40-kDa linked, because neither ester-bonded 65 kDa HC nor 65 kDa-40 kDa fragments were observed, nor was a 40-kDa peptide released after hydroxylamine cleavage. Factor I and CR1 cleaved the C3b2-IgG molecule to its final physiological product, C3dg2-IgG, which migrated as a 133-kDa fragment in reduced form. This fragment released exclusively C3dg (the final physiological product of C3b inactivation by factor I) and IgG HC. C3dg2-HC appeared as a double band on SDS-PAGE only at low gel porosity, suggesting the presence of two conformers of the same composition. Our results suggest that, upon physiological inactivation, C3b2-IgG complexes retain dimeric inactivated C3b and C3dg, which allows bivalent binding to the corresponding complement receptors.

Assembly and regulation of the complement amplification loop in blood: the role of C3b-C3b-IgG complexes

Amplification of complement activation in blood and serum starts on multi-protein complexes that act as precursors of an alternative C3 convertase. Among these covalently linked C4b-, C3b-, and IgG-containing complexes C3b-C3b-IgG complexes represent the major species containing C3b and IgG. Recent work on their purification and characterization is discussed. Special emphasis is placed on the arrangement of ester bonds in these complexes and their dual type of partial protection from inactivation. Partial protection from inactivation is mediated by properdin which binds to these complexes in the complete absence of any other complement protein. High dose IgG, known to stimulate inactivation of these complexes, appears to lower properdin binding in a process that also involves factor H. Properdin stimulates factor B binding to these complexes and renders them far better precursors of a C3 convertase than C3b. The available information allows a suggestion for a new scheme on how the amplification loop is assembled and regulated in blood and serum.

A C3 convertase assay for nephritic factor functional activity

C3 nephritic factor (C3NeF) is an autoantibody against the C3 convertase which stabilizes this otherwise inherently labile neoenzyme and induces a continuous activation of the alternative pathway with C3 depletion. NeF is found in patients with membranoproliferative glomerulonephritis and/or partial lipodystrpohy. NeF activity is usually detected in plasma by hemolytic tests. In order to obtain reproducible data for the functional activity of purified C3NeF IgG a solid phase assay was developed. C3 convertase was generated on immobilized C3b by incubation with factors B and D in the presence of Ni(2+). Convertase sites were left to decay in the presence of normal IgG or NeF IgG. Residual convertase activity was measured by adding 125I-C3 and capturing nascent 125I-C3b on the plate surface via covalently coupled NH2-Glu-Tyr dipeptide. In the presence of factor H during C3 convertase decay, a dose dependent stabilizing activity was shown for NeF IgG including NeF IgG purified from urine. A second format of the assay was developed in which C3 convertase was assembled on C3b(2)-IgG complexes in the presence of Mg(2+). Since these complexes are more efficient as convertase precursors the signal was five-fold higher than with C3b. Convertase decay, on the other hand, was not influenced by the nature of the precursor and in both systems the stabilizing activity of NeF IgG was similar.