Characterization of an anti-digoxin antibody binding site by site-directed in vitro mutagenesis.

In vitro mutagenesis and immunoglobulin gene transfection were used to investigate the binding site of a monoclonal antibody, 2610, that binds to digoxin, a cardiac glycoside. A computer model was generated in order to select sites in the complementarity determining regions (CDR) that would participate in binding. Residues in the CDR segments were chosen that possess high solvent exposure and were located in a putative cleft. The cloned heavy and light chain variable regions were subjected to in vitro mutagenesis at these sites. The mutated variable regions in M13 were then subcloned into expression vectors and transfected. The affinities and specificity binding properties of the resultant expressed antibodies were measured. Many of the mutants of the putative contact residues showed significant but not major alterations of binding properties. Since most of the residues in the binding site are non-polar and aromatic and since many of the mutations resulted in only modest binding changes, we theorize that much of the high affinity binding (> 10(9)/M) is the cumulation of many weak interactions, arising from dispersion forces and hydrophobic effects in the pocket. Preliminary mutagenesis of two L chain positions proposed to bind to the lactone end of digoxin have larger binding effects. Specificity studies show that the mutants more frequently possess altered binding to the lactone ring of digoxin that altered binding to other digoxin moieties. The data are most suggestive of a model in which lactone is at the bottom of a binding pocket, followed by the steroid nucleus and then by the sugar moiety extruding out of the pocket. The binding information may be useful in understanding the immune response to large, hydrophobic haptens.

Altered hapten recognition by two anti-digoxin hybridoma variants due to variable region point mutations.

Two spontaneous variants of the murine anti-digoxin antibody-producing hybridoma cell line 26-10 were isolated by two-color fluorescence-activated cell sorting on the basis of altered hapten binding. The variable region sequences of the antibodies produced by the mutant lines revealed that each contains a single amino acid change in the heavy chain second complementarity determining region. A Tyr to His change at position 50 leads to a 40-fold reduction in affinity for digoxin. A Ser to Phe mutation at position 52 results in a 300-fold reduction in affinity for digoxin. A competition assay involving 33 digoxin analogues was used to examine the specificity of hapten binding of 26-10 and the two mutant antibodies. The position 50 mutant has a distinct specificity change; it exhibits a preference for digoxin congeners containing a hydroxyl group at the steroid 12 position, whereas the 26-10 parent does not. The affinities of all three antibodies for hapten are progressively lowered by substitutions of increasing size at the digoxin steroid D ring 16 position. Although 26-10 binds digoxin and its genin form equally, 12 and 16 steroid position substitutions which lower affinity also confer a preference for a sugar at the steroid 3 position. These results suggest that position 50 contributes to specificity of the antibody and that alterations of the hapten can lead to differences in recognition, possibly through a shift in hapten orientation within the binding site.

The specificity properties that distinguish members of a set of homologous anti-digoxin antibodies are controlled by H chain mutations.

Five murine A/J strain anti-digoxin mAb (35-20, 40-40, 40-120, 40-140, and 40-160) have highly homologous H and L chain V regions, only differing by somatic mutation, yet differ in affinity and specificity. The availability of the VH and VL genomic clones from one hybridoma, 40-140, has now allowed studies involving in vitro mutagenesis and chain recombination among these five hybridomas. To determine the relative contributions of the mutations found in either VH or VL to the overall binding properties of these antibodies, we recombined the 40-140VH with the VL of each hybridoma. The 40-140VH gene was transfected into hybridoma variants that produce only VL. The recombinant antibodies show that the mutations present in VH, rather than in VL, affect the fine specificity properties of these antibodies, whereas, the mutations among both VH and VL chains are important in determining antigen affinity. From mutations present in VH that affect fine specificity properties, the comparison of the antibody sequences, and from the previously measured binding properties, we predicted and tested selected VH mutations for their ability to alter specificity or affinity by doing site-directed in vitro mutagenesis. The results for the somatic mutations found in this group of antibodies show: 1) VH mutations control the fine specificity properties that distinguish different members of this group; 2) in particular, VH residues 54 and 55 in CDR2 control the distinguishing characteristics of specificities between these antibodies; and 3) by mutagenesis, we had the unusual result of being able to alter Ag specificity without affecting affinity. A computer model of the 40-140 antibody binding site was generated which indicates that VH residues 54 and 55 are highly accessible.

A V kappa-J kappa junctional change in an antidigoxin recombinant antibody destroys digoxin-binding activity.

A set of high affinity antidigoxin antibodies were previously identified with high homologous V kappa 1A L chain sequences but were associated with two entirely different VH regions and two dramatically different specificities for digoxin analogs. Antibodies 40-20, 40-60, 40-90, and 40-100 displayed similar binding specificities but differed from that of antibody 26-10. In a previous study using somatic cell fusion for Ig chain recombination we demonstrated that a recombinant antibody consisting of the H chain of antibody 26-10 and the L chain of antibody 40-20 retained digoxin binding and the 26-10 Id, but displayed a binding specificity pattern dominated by the 26-10 H chain donor. In the present study we produced three additional chain recombinant antibodies that contain the 26-10 H chain recombined with each of the L chains of antibodies 40-60, 40-90, and 40-100. All four recombinants expressed the 26-10 Id indistinguishably from the 26-10 antibody. Two of the recombinants (using the 40-60 and 40-90 L chains) bind digoxin; however, the recombinant using the 40-100 L chain failed to bind digoxin. Complete sequence analyses of the 40-20, 40-60, 40-90, and 40-100 VH and VL regions were performed. Antibodies 40-90 and 40-100 have identical VH region sequences but differed only in their L chains at position 96 (proline/leucine). This single difference at the VK-JK junction abolished digoxin binding in the context of one H chain (26-10), but does not cause a significant change in binding in association with the "normal" parental chains 40-90 and 40-100. Thus, structurally closely related VL regions can recombine with different VH regions to form digoxin binding sites of different specificity; in one binding site the identity of a L chain junctional residue is critical whereas in the second binding site that residue is unimportant. Molecular modeling studies revealed major differences between calculated binding site structures for 26-10 when leucine is substituted for proline at position 96 in the 26-10 VL region.

Heavy and light chain contributions to antigen binding in an anti-digoxin chain recombinant antibody produced by transfection of cloned anti-digoxin antibody genes.

We used immunoglobulin gene transfection to study the effect that substituting an homologous light (L) chain for a parental L chain has on antigen fine specificity and affinity. High-affinity monoclonal anti-digoxin antibodies 26-10 and 40-100 were selected for study because their L chains are 92% homologous (although the H chains differ), and their binding with digoxin and digoxin analogs show very different properties. In order to generate a recombinant transfectoma, the genes encoding the 26-10 H and L chains were cloned. After the sequenced clones had been shown to contain the V gene and the transcriptional control elements, the H and L chain V region genes were subcloned into different expression vectors. Both constructs were transfected into myeloma J558L, a lambda 1 chain producer, to verify that the genetic constructs expressed correctly. The recombined 26-10 antibody was identical to parental 26-10 antibody in fine specificity and affinity. The 26-10 L chain construct was then transfected into a cell line, CR-101, that expresses the 40-100 H chain and a lambda 1 chain. The transfectoma 1E6, secreting 40-100 H chain and 26-10 L chain, was selected. Appropriate gene expression in 1E6 was proven by polymerase chain reaction cloning and sequencing. The fine specificity properties of the 1E6 recombinant derive from both the 40-100 and 26-10 antibodies; however, the affinity of 1E6 is 130 times less than that of the parental antibodies. We conclude that, in 1E6, the H and L chains are codominant in their influence on antigen specificity and that homologous pairing of H and L chains is required for optimal affinity.

A bifunctional fusion protein containing Fc-binding fragment B of staphylococcal protein A amino terminal to antidigoxin single-chain Fv.

A bifunctional molecule was genetically engineered which contained an amino-terminal effector domain that bound immunoglobulin Fc (fragment B of staphylococcal protein A) and a carboxyl-terminal domain that bound digoxin [a single-chain Fv (sFv)]. Effector and sFv binding properties were virtually identical with those of the parent molecules, despite the proximity of the FB to the sFv combining site. This finding is unprecedented since in all molecules of the natural immunoglobulin superfamily, the antigen binding domain is amino terminal to the effector domain. The FB-sFv sequence was encoded in a single synthetic gene and expressed as a 33,106 molecular weight protein in Escherichia coli. After purification, renaturation, and affinity isolation, yield of active fusion protein were 110 mg/L of fermented cells (18.5-g cell paste). Bifunctionality was confirmed by the ability of FB-sFv to cross-link IgG to digoxin-bovine serum albumin, as measured by plate assays and by Ouchterlony analysis. Analysis of the expressed fusion protein suggests that the sFv holds promise for the development of multifunctional, targetable single-chain proteins.

Expression of a hybrid immunoglobulin-T cell receptor protein in transgenic mice.

We have constructed a hybrid immunoglobulin (VDJH)-T cell receptor (C alpha) gene using the VDJH exon from a digoxin-specific antibody. This gene was used to make a line of transgenic mice. The hybrid VDJH-C alpha protein is expressed on a subset of T cells in these mice, and we have shown that it forms part of a functional TCR complex by the criteria of coprecipitation and comodulation of CD3 and TCR beta chain components and T cell activation with anti-idiotypic antibodies or digoxin. Furthermore, in cells expressing the hybrid protein, there is allelic exclusion of endogenous TCR alpha genes. We discuss the implications for the comparative structure of T cell receptors and immunoglobulins.

Protein engineering of antibody binding sites: recovery of specific activity in an anti-digoxin single-chain Fv analogue produced in Escherichia coli.

A biosynthetic antibody binding site, which incorporated the variable domains of anti-digoxin monoclonal antibody 26-10 in a single polypeptide chain (Mr = 26,354), was produced in Escherichia coli by protein engineering. This variable region fragment (Fv) analogue comprised the 26-10 heavy- and light-chain variable regions (VH and VL) connected by a 15-amino acid linker to form a single-chain Fv (sFv). The sFv was designed as a prolyl-VH-(linker)-VL sequence of 248 amino acids. A 744-base-pair DNA sequence corresponding to this sFv protein was derived by using an E. coli codon preference, and the sFv gene was assembled starting from synthetic oligonucleotides. The sFv polypeptide was expressed as a fusion protein in E. coli, using a leader derived from the trp LE sequence. The sFv protein was obtained by acid cleavage of the unique Asp-Pro peptide bond engineered at the junction of leader and sFv in the fusion protein [(leader)-Asp-Pro-VH-(linker)-VL]. After isolation and renaturation, folded sFv displayed specificity for digoxin and related cardiac glycosides similar to that of natural 26-10 Fab fragments. Binding between affinity-purified sFv and digoxin exhibited an association constant [Ka = (3.2 +/- 0.9) x 10(7) M-1] that was about a factor of 6 smaller than that found for 26-10 Fab fragments [Ka = (1.9 +/- 0.2) x 10(8) M-1] under the same buffer conditions, consisting of 0.01 M sodium acetate, pH 5.5/0.25 M urea.

Variable region framework differences result in decreased or increased affinity of variant anti-digoxin antibodies.

Rare spontaneous variants of the anti-digoxin antibody-producing hybridoma 40-150 (Ko = 5.4 x 10(9) M-1) were selected for altered antigen binding by two-color fluorescence-activated cell sorting. The parent antibody binds digoxin 890-fold greater than digitoxin. The variant 40-150 A2.4 has reduced affinity for digoxin (Ko = 9.2 x 10(6) M-1) and binds digoxin 33-fold greater than digitoxin. A second-order variant, derived from 40-150 A2.4 (designated 40-150 A2.4 P.10), demonstrated partial regain of digoxin binding (Ko = 4.4 x 10(8) M-1). The altered binding of the variant 40-150 A2.4 was accounted for by a point mutation resulting in substitution of arginine for serine at position 94 in the heavy chain variable region. Antibody 40-150 A2.4 P.10 also contains this arginine but owes its enhanced antigen binding to deletion of two amino acids from the heavy chain amino terminus. This unusual sequence alteration in an immunoglobulin framework region confers increased affinity for antigen.

Immunoglobulin chain recombination among antidigoxin antibodies by hybridoma-hybridoma fusion.

Conditions necessary for in vitro chain recombination of high affinity (10(9) to 10(12) M-1) antidigoxin monoclonal antibodies resulted in decreased affinity for both intact "native" and chain recombinant molecules. Chain recombination by somatic cell fusion was used instead to study the effects on antigen specificity and idiotypy of recombinants in which an homologous light (L) chain substituted for the parental L chain. The antidigoxin antibody 26-10 utilizes a VL sequence highly homologous to that of antibody 40-20, an antidigoxin antibody which uses a different VH gene than does 26-10 and lacks significant reactivity with an anti-26-10 idiotypic serum. The drug-marked antidigoxin cell line 26-10 (gamma 2a, kappa) and a drug-marked light chain producing variant of antidigoxin hybridoma 45-20 (lambda 1) which lacks both digoxin binding and idiotypy were fused. The fusion progeny (gamma 2a, kappa, lambda 1) which binds digoxin and is idiotype-positive, was selected for kappa loss (resulting in loss of digoxin and idiotype binding) and then fused with a heavy (H) chain loss variant of antidigoxin hybridoma 40-20 (kappa, digoxin nonbinding, idiotype negative). The resultant cell line CR-57 (gamma 2a, kappa, lambda) secretes antibodies which assemble the 26-10 H chain with both the 40-20 kappa-chain and the 45-20 lambda 1-chain. The affinity purified recombinant species consisting of 26-10 H chain and 40-20 kappa-chain expresses complete 26-10 idiotypic determinants. However, this recombinant antibody binds digoxin with decreased affinity and altered specificity relative to native 26-10. The binding specificity pattern nonetheless is most similar to the H chain donor. Amino acid and nucleotide sequence analyses of the respective light chains demonstrate six variable region differences between them, two of which are in complementarity-determining regions and the remainder in the framework. Hybridoma-hybridoma fusion provides an alternative to in vitro chain recombination for studying the contribution of chain combinational diversity to antibody diversity, antigen binding, and idiotypy.

Detection of Müllerian inhibiting substance in biological samples by a solid phase sandwich radioimmunoassay.

Müllerian inhibiting substance (MIS) is a 140,000-dalton glycoprotein responsible for regression of Müllerian ducts in a male embryo. It has recently been demonstrated that MIS inhibits the growth of tumors in vivo and in vitro. In this study, we have constructed a sensitive, solid phase sandwich RIA using monoclonal antibodies raised to bovine MIS. The amount of MIS detected was based on the protein concentration of Green 3, the most purified fraction of MIS available. The assay could detect 20 ng Green 3 or 0.14 pmol in physiological samples. There was no evidence of cross-reactivity of the antibodies raised to bovine MIS with chicken, rat, mouse, or human MIS.

Monoclonal antibodies as molecular probes to study structural heterogeneity between human and animal renins and other aspartyl proteinases.

Monoclonal antibodies may be helpful in comparing the structural homology of renins of various animal species as well as other aspartyl proteinases. We obtained four hybridoma lines secreting monoclonal antibodies that inhibited 3 Goldblatt mU human renin enzymatic activity with apparent IC50 of 1.1 X 10(-6)-4 X 10(-8) M. Each antibody was specific for human renin and did not cross-react either with other proteins tested nor with renins of other species in an immunoradiometric assay. These antibodies did not inhibit the enzymatic activities of nonprimate renins or nonrenin aspartyl proteinases tested. These data indicate that certain structural determinants of human renin activity may be uniquely different from those of nonprimate renins or nonrenin aspartyl proteinases.

Binding and structural diversity among high-affinity monoclonal anti-digoxin antibodies.

High-affinity monoclonal antibodies specific for the cardiac glycoside digoxin provide a useful system for the study of structure-function relationships between antibody combining site and specific antigenic determinants. Fifteen high-affinity monoclonal anti-digoxin antibodies were produced when spleen cells from A/J mice immunized with digoxin coupled to human serum albumin (Dig-HSA) were fused with the non-secreting murine myeloma Sp2/0 cell line. Each subcloned hybridoma antibody was analyzed for affinity and specificity for structurally related cardiac glycosides by a radioimmunoassay based on the adsorption of free [3H]digoxin to dextran-coated charcoal. All of the anti-digoxin hybridoma proteins demonstrated high affinity constants ranging from 10(9) to 10(12) M-1. Using seven different analogs of digoxin, binding specificities of the monoclonal antibodies were assessed by inhibition radioimmunoassay. The 15 hybridomas produced from fusions involving five mice could be divided into eight sets on the basis of these binding specificities. Certain antibodies exhibit a preference for the aglycone portion of digoxin, while others are more specific for the tridigitoxose sugar moiety of digoxin. Monoclonal antibody H- and L-chains were subjected to N-terminal amino acid sequence analysis. The antibodies may be divided into several sequence homology sets for both H- and L-chains. In most instances, homologous heavy chains are associated with a set of homologous light chains. Homologous partial sequences, however, do not correlate with similar antigenic specificities and affinities for digoxin. Thus the fine specificity for antigen is not dependent on VH- and VL-encoded sequences alone. These data illustrate the broad diversity of the elicited response to a single hapten, even in inbred mice.

Reversal of lethal digoxin toxicity in guinea pigs using monoclonal antibodies and Fab fragments.

To extend the potential application of digoxin-specific immunoglobulin (Ig) (Fab) fragments for the reversal of advanced digitalis intoxication, monoclonal digoxin-specific antibodies were obtained by fusion of myeloma cell lines with spleen cells from mice immunized with a digoxin-serum albumin conjugate. The monoclonal antibody from the cell line designated Dig 26-10 had high affinity (KA = 5 X 10(9) M-1) and specificity for digoxin and was tested for its efficacy in the reversal of advanced, otherwise lethal digoxin toxicity in guinea pigs given a loading dose of 500 micrograms of digoxin per kg b.wt. i.v. followed by continuous infusion of digoxin at 10 (IgG-treated group) or 50 (Fab-treated group) microgram/kg/min. Control animals given nonspecific rabbit or mouse Igs after the onset of digoxin-toxic ventricular arrhythmias all died. Administration of monoclonal digoxin-specific antibody as intact IgG in doses stoichiometrically equivalent to the digoxin dose fully reversed digoxin toxicity in six of eight animals and prolonged survival somewhat in the remaining two animals. Fab fragments from the Dig 26-10 monoclonal antibody were even more effective, with rapid reversal (mean time 7 min) of all arrhythmias and survival of all animals so treated. We conclude that murine monoclonal antibodies and their Fab fragments are capable of reversing advanced and otherwise lethal digoxin-induced arrhythmias in a guinea-pig experimental model and offer potential advantages over polyclonal antibodies in the management of this clinically important problem.

Production of monoclonal antibodies for affinity purification of bovine mullerian inhibiting substance activity.

Two monoclonal antibodies (IG8 and IG10) specific for Mullerian inhibiting substance (MIS) were obtained from the fusion between myeloma cell line SP2/0 and spleen cells from an A/J mouse immunized with partially purified MIS. The resulting hybridomas were screened by a solid-phase RIA and two lines were selected and cloned. Both MAbs IG8 and IG10 subsequently demonstrated specificity for MIS by their ability to inhibit biologically active MIS by precipitation with a second antibody, directly block MIS activity in the organ culture assay, and adsorb and elute active MIS when coupled to a solid support. SDS-polyacrylamide gel electrophoresis of affinity purified MIS demonstrated a major band at 140 kD in unreduced gels and two bands with approximate molecular weights of 70 and 74 KD following reduction. Protein bands were localized either directly by silver staining or on immunoblots developed with radiolabeled anti-MIS MA.

A monoclonal antibody specific for the carboxy-terminus of angiotensin II.

A monoclonal antibody specific for the carboxy-terminus of angiotensin II was produced from the somatic cell fusion between SP2/0 myeloma cells and spleen cells from CAF/J mice immunized with angiotensin II selectively coupled to thyroglobulin. The subcloned line D5-7R2 was augmented in the ascites form and shown to be specific for angiotensin II (octapeptide) and shorter angiotensin peptides. This antibody, however, did not cross-react with angiotensin I (decapeptide). This selectivity will be important in clinical assays that measure angiotensin II in the presence of angiotensin I.

Antibodies as specific renin inhibitors: studies with polyclonal and monoclonal antibodies and Fab fragments.

The use of antirenin antibody and Fab may provide a more specific physiologic tool and potential therapeutic agent than the existing pharmacologic inhibitors. The antibody combining site, by virtue of its larger size than organic compounds, has the capacity for a larger number of intramolecular contacts with its ligands, thus allowing increased selectivity and affinity. Renin-specific Fab obtained through immunization with purified dog renal renin has been studied. Fab had no effect on blood pressure in the sodium replete conscious dog but induced systemic hypotensive responses in the sodium deplete animal or during acute renovascular hypertension. These responses were accompanied with complete suppression of plasma renin and angiotensin II levels. The vasodepressor responses of Fab were comparable to the converting enzyme inhibitor, teprotide. However, the latter induced a greater renal vasodilator effect. Since antibodies and their fragments derived from immune sera are limited in their application to physiologic study with respect to lack of homogeneity, reproducibility and limitation of quantity, we obtained monoclonal antibodies to purified human renal renin. Fusion HR3 yielded 14 renin-antibody secreting clones. Six clones have been isolated and characterized. Isotypes include IgG1 and IgM. Kd's range from 6 X 10(-9) to 7.5 X 10(-10)M renin concentration. Five clones produce antibodies with antienzymatic activity. IC50's of these antibodies range from 1 X 10(-6) to 6 X 10(-8)M. All antibodies are renin-specific and do not bind several nonrenin enzymes and proteins examined. They are also highly species specific, i.e., do not crossreact with mouse, dog, bovine or rat renins but recognize hog renin. These catalytic-site directed antibodies may be highly potent and specific tools for physiologic studies in subhuman primates and man.