Thioether-bonded constructs of Fab'gamma and Fc gamma modules utilizing differential reduction of interchain disulfide bonds.

We describe a two-stage preparation of chemically engineered Ab constructs, employing as modules Fab'gamma from mAb or rAb, and Fc from human normal IgG1. A multivalent, optionally multispecific F(ab')(n) core is formed in stage one, and one or more Fc modules added in stage two. Examples include bispecific Fab(2)Fc(2) (for simplicity, primes and Greek letters are omitted from names of final constructs) and trivalent Fab(3)Fc(2), which are designed to kill neoplastic cells. An essential element in the construction is the availability of the Fab' in two reduced forms, Fab'(-sulfhydryl (SH))(5) and Fab'-SH. The first is obtained by full reduction of the interchain disulfide bonds (SS) in the F(ab')(2) fragment of IgG. Fab'-SH is obtained by disulfide-interchange reactions on Fab'(-SH)(5), whereby the gamma-light SS is reconstituted, an unusual intrachain SS forms in the gamma-chain hinge, and one hinge SH remains. F(ab')(2) and F(ab')(3) cores are built using partially reduced modules, being given intermodular thioether links that resist reduction. These cores are then fully reduced, making available SH groups for addition of the Fcgamma modules. In the final constructs, all intermodular links embody tandem thioether bonds arising at hinge-region cysteines. Cytotoxic activities of representative constructs, and some enhancements deriving from multiple modules, are assessed. In guinea pigs, catabolism of Fab(2)Fc(2) yielded a t(1/2) similar to that of human IgG1, although the serum Fab(2)Fc(2) revealed some proteolytic breakdown not shown by the IgG1. Immunotherapy of a guinea-pig leukemia confirmed the ability of these constructs to kill target cells in vivo.

Conjugation of human Fc gamma in closed-hinge or open-hinge configuration to Fab'gamma and analogous ligands.

We describe a method for linking human normal Fc gamma1, via stable thioether bonds emerging from its hinge, to any molecule expressing a free sulfhydryl (SH) group. The Fc hinge may be closed by a disulfide (SS) bond or left open. Preparation begins with reduction of the Fc hinge to release four SH groups from its two parallel inter-gamma SS bonds. When the Fc is required in normal closed-hinge configuration, one SH group is alkylated with N-ethylmaleimide under limiting conditions, and one of the inter-gamma SS bonds is reconstituted by SS interchange. The residual SH group, to be used for linking, is left as a 4-dithiopyridyl group suitable for storage. When the Fc is required for conjugation the 4-dithiopyridyl is replaced by a metastable maleimidyl group, which reacts rapidly with SH on the partner molecule to form a tandem thioether link. If the partner is Ab Fab'gamma, linking to cysteines in the Fab'gamma hinge yields derivatives such as FabFc and FabFc2. Chimeric FabFc Abs (mouse Fab'gamma/human Fc gamma1) invoked cellular cytotoxicity in vitro, using human cell lines as targets and human lymphocytes as effectors, whether the Fc hinge was open or closed. The same Abs could kill the same targets by activating human complement, but only when the Fc hinge was closed. Both effector functions were enhanced by the presence of a second Fc in FabFc2. This method of Fc addition can be used to predict the performance of recombinant chimeric Abs and to provide novel molecular geometries.

Bispecific F(ab' gamma)2 antibody for the delivery of saporin in the treatment of lymphoma.

This work describes the successful use of bispecific F(ab' gamma)2 antibody (Ab) in combination with a ribosome-inactivating protein (RIP), saporin, for the treatment of neoplastic disease in vivo. A total of three thioether-linked F(ab' gamma)2 heterodimers were prepared, each having dual specificities for saporin and the guinea pig lymphoblastic leukemia, L2C. In all three cases specificity for the L2C cells was provided by a high affinity mouse anti-idiotype (anti-Id) mAb, whereas the antisaporin activity came from either one of two mouse mAb or an affinity-purified rabbit polyclonal Ab. In vitro studies, measuring protein synthesis, showed that all three derivatives were extremely efficient at delivering saporin to L2C cells, to the extent that addition of the rabbit Fab' gamma-containing bispecific Ab to cell culture at 1 microgram/ml increased the toxicity of saporin (50% inhibiting concentration) by close to 90,000-fold. Similarly, in leukemic guinea pigs, a small dose of saporin (10 micrograms) which by itself showed no therapeutic effect, was able to completely eradicate Id-positive tumor when given in combination with an excess of bispecific Ab. Although tumors did eventually emerge in most of these animals, immunofluorescence analysis showed that in almost all instances the escaping cells were Id- variants of the L2C. Experiments to define the optimal treatment regimen in this model showed that, although the administration of saporin and bispecific Ab at separate sites could be therapeutically effective, mixing the Ab and saporin to form immune complexes before injection did generally enhance their performance. A molar surplus of bispecific Ab in these mixtures both extended the metabolic survival of the saporin and enhanced the therapeutic performance, with molar ratios above 3:1 generally being required for optimum treatment when using saporin at 10 micrograms. Derivatives containing polyclonal antisaporin were more efficient than those containing mAb, yielding optimum therapeutic results with a molar ratio of 1.5:1 when combined with 10 micrograms saporin. These findings have shown that bispecific F(ab' gamma)2 Ab, as well as being straightforward to prepare, can also function as an extremely efficient vector for delivering cytotoxic agents such as ribosome-inactivating protein to unwanted cells in vivo.

Preparation and performance of bispecific F(ab' gamma)2 antibody containing thioether-linked Fab' gamma fragments.

A simple and efficient method is described for the production of pure bispecific F(ab' gamma)2 heterodimers, in which the individual antibody Fab' gamma fragments are joined via a stable thioether linkage. Hybrid molecules were constructed from both mouse monoclonal and rabbit polyclonal antibodies with equal efficiency, in the combinations mouse-rabbit and mouse-mouse. Peptic F(ab' gamma)2 fragments from the two chosen antibodies were first reduced to provide Fab' gamma SH. The SH groups on one of the Fab' gamma SH partners were then fully alkylated with o-phenylenedi-maleimide to provide free maleimide groups. Finally the two preparations, Fab' gamma mal and Fab' gamma SH, combined under conditions which allowed cross-linking of the maleimide and SH groups and avoided reoxidation of SH groups. The major product isolated from the reaction mixture after chromatography was always the F(ab' gamma)2 heterodimer (50 to 70%), other products being unreacted Fab' gamma and trace amounts of putative F(ab' gamma)3. Immunochemical analysis revealed that the thioether-linked F(ab' gamma)2 molecules were essentially all heterodimers, most of which had been joined via their Fd chains. The dual specificity of F(ab' gamma)2 heterodimers was tested functionally in three systems: 1) the combination (anti-idiotype + anti-phycoerythrin) linked L2C cells to the fluorochrome phycoerythrin, allowing fluorescence analysis; 2) the combination (anti-idiotype + anti-saporin) linked L2C cells to the ribosome-inactivating protein saporin, and transformed a subtoxic dose of saporin into a highly toxic mixture which prevented further protein synthesis by L2C cells; and 3) the combination of anti-idiotype with 3G8 (antibody to the Fc gamma receptor CD16) subjected L2C cells to cytotoxic attack by human mononuclear effectors.

Emergence of immunoglobulin variants following treatment of a B cell leukemia with an immunotoxin composed of antiidiotypic antibody and saporin.

The potency and specificity of immunotoxins consisting of monoclonal antiidiotype conjugated to the ribosome-inactivating protein, saporin, have been evaluated in the treatment of guinea pig L2C B lymphocytic leukemia. The immunotoxins were therapeutically much more effective than their parent antibodies. Their specificity reflected that of their antiidiotype component. Although the leukemia emerged eventually in most animals treated with these conjugates, most of the cells showed altered Ig expression, which rendered them resistant to the therapy. Commonly, the emerging cells had lost mu heavy chain production, leaving them negative for intracellular, surface, and secreted IgM, but still positive for lambda light chain production. In addition, a minor group of L2C variants was identified in a protocol designed to detect mutants at very low frequency: here the cells were exposed in vitro to immunotoxin and, while still viable as judged by dye-exclusion, inoculated in large numbers into animals. In tumor that emerged under these circumstances, the majority of cells were again immunoglobulin-negative; however a minority exhibited IgM with an altered idiotype (Idiotope-loss variants), rendering them unreactive with immunotoxin. Immunotherapy with unmodified anti-Id antibody alone does not reveal these variants, and we suggest it is the increased selective force exerted by the highly potent immunotoxins that allow these minor nonreactive populations to emerge.