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 cofi 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. colt codon preference, and the sFv gene was assembled starting from synthetic oligonucleotides. The sFv polypeptide was expressed as a fusion protein in E. colt, 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 afirmity-purified sFv and digoxin exhibited an association constant [Ka = (3.2 ± 0.9) x 107 M -1] that was about a factor of 6 smaller than that found for 26-10 Fab fragments [K. = (1.9 @ 0.2) x 108 M 'I under the same buffer conditions, consisting of 0.01 M sodium acetate, pH 5.5/0.25 M urea.It is known that antigen binding fragments of antibodies (1,2) can be refolded from denatured states with recovery of their specific binding activity (3)(4)(5)(6). The smallest such fragment that contains a complete binding site is termed Fv, consisting of an Mr 25,000 heterodimer of the VH and VL domains (2, 5-11). Givol and coworkers were the first to prepare an Fv by peptic digestion of murine IgA myeloma MOPC 315 (2). However, subsequent development of general cleavage procedures for Fv isolation has met with limited success (7-11). As a result, the Mr 50,000 Fab (1) has remained the only monovalent binding fragment used routinely in biomedical applications.An Fv analogue was constructed in which both heavy-and light-chain variable domains (VH and VL) were part of a single polypeptide chain. Synthetic genes for the 26-10 anti-digoxin VH and VL regions were designed to permit their connection through a linker segment, as well as other manipulations (12,13 MATERIALS AND METHODSModel Antibody. The digoxin binding site of the IgG2a,K monoclonal antibody 26-10 has been analyzed by MudgettHunter and colleagues (14-16). The 26-10 V region sequences were determined from both protein sequencing (17) (14) and has a well-defined specificity profile (15) (Fig. 1).Gene Synthesis. Design of the 744-base sequence for the synthetic sFv gene was derived from the sFv protein sequence by choosing codons preferred by E. coli (25). Synthetic genes encoding the trp promoter-operator, the modified trp LE leader peptide (MLE), and VH were prepared largely as described (26). The gene encoding VH was assembled from 46...
Radiolabeled single-chain Fv (sFv) molecules display highly specific tumor retention in the severe combined immunodeficient (SCID) mouse model; however, the absolute quantity of sFv retained in the tumors is diminished by the rapid renal elimination resulting from the small size of the sFv molecules (M r 27,000) and by dissociation of the monovalent sFv from tumor-associated antigen. We previously reported significant improvement in tumor retention without a loss of targeting specificity on converting monovalent sFv into divalent [(sFvV) 2 ] dimers, linked by a disulfide bond between COOH-terminal cysteinyl peptides engineered into the sFvV . However, our data for enhanced dimer localization in tumors could not distinguish between the contributions of enhanced avidity and increased systemic retention associated with the larger size of 54 kDa [(sFvV) 2 ] dimers relative to 27-kDa sFv. In this investigation, we have compared tumor targeting of divalent antic-erbB-2/HER2/neu 741F8-1 (sFvV) 2 homodimers with monovalent 741F8/26-10 (sFvV) 2 heterodimers (M r 54,000) and 741F8 sFv monomers (741F8 sFv has binding specificity for erbB-2/ HER2/neu and 26-10 sFv specificity for digoxin and related cardiac glycosides). These studies allowed us to distinguish the dominant effect of valency over molecular weight in accounting for the superior tumor retention of 741F8-1 (sFvV) 2 homodimers. Each of the radioiodinated species was administered i.v. to SCID mice bearing SK-OV-3 human tumor xenografts and tumor localization at 24 hours post i.v. injection was determined for 125 I-741F8-1 (sFvV) 2 (3.57 %ID/g), 125 I-741F8/26-10 (sFvV) 2 (1.13 %ID/g), and 125 I-741F8-1sFv (1.25 %ID/g). These findings substantiate that the improved tumor retention of (sFvV) 2 homodimers over sFv monomers results from the availability of dual binding sites rather than from the slower systemic clearance of homodimers.Antibody engineering permits the design of new antibodybased proteins that can potentially address the shortcomings of intact antibodies as cancer therapeutics (1). One approach has been to produce the minimal antibody binding site in the form of a single-chain Fv (sFv), comprising the heavy and light chain variable domains of an antibody, joined by an appropriate linker peptide (2, 3). These 26-to 27-kDa sFv antibody species can be engineered from monoclonal antibodies or selected from phage-antibody libraries to obtain monovalent sFv species with high affinity and specificity for a target of choice. We have previously investigated the advantage of targeting tumors with sFv dimers, prepared as disulfide-linked (sFvV) 2 (4) or noncovalent diabodies (5), and in both cases dimeric/divalent species showed significant improvement over monomers. This investigation addresses the specific contributions of valence and molecular size to the in vitro binding characteristics and in vivo tumor targeting of sFv monomers and dimers.This investigation was based on our preparation of 741F8-1 sFv monomers, dimers, and bispecific heterodimers (4...
A single-chain antibody or single-chain Fv (sFv) incorporates the complete antibody binding site in a single polypeptide chain of minimal size, with an approximate molecular weight of 26,000. In antibodies, the antigen combining site is part of the Fv region, which is composed of the VH and VL variable domains on separate heavy and light chains. Efforts over nearly two decades have indicated that Fv fragments can only rarely be prepared from IgG and IgA antibodies by proteolytic dissection. Beginning in 1988, single-chain analogues of Fv fragments and their fusion proteins have been reliably generated by antibody engineering methods. The first step involves obtaining the genes encoding VH and VL domains with desired binding properties; these V genes may be isolated from a specific hybridoma cell line, selected from a combinatorial V-gene library, or made by V gene synthesis. The single-chain Fv is formed by connecting the component V genes with an oligonucleotide that encodes an appropriately designed linker peptide, such as (Gly4-Ser)3. The linker bridges the C-terminus of the first V region and N-terminus of the second, ordered as either VH-linker-VL or VL-linker-VH. In principle, the sFv binding site can faithfully replicate both the affinity and specificity of its parent antibody combining site, as demonstrated in our model studies with the 26-10 anti-digoxin sFv. Furthermore, the sFv remains stable at low concentrations that promote VH and VL dissociation from the Fv heterodimer, resulting in loss of Fv binding. Intravenously administered sFv proteins exhibit accelerated biodistribution and exceptionally fast clearance compared to IgG or Fab. These pharmacokinetic properties allow rapid imaging by sFv, which therefore may be labeled with a short-lived isotope such as Tc-99m. Expression of a single gene product from fused sFv and effector genes facilitates immunotargeting of the effector protein, as shown for single-chain Fv toxin fusion proteins.
We describe a method to facilitate radioimaging with technetium-99m (99mTc) by genetic incorporation of a 99mTc chelation site in recombinant single-chain Fv (sFv) antibody proteins. This method relies on fusion of the sFv C terminus with a Gly4Cys peptide that specifically coordinates 99mTc. By using analogues of the 26-10 anti-digoxin sFv as our primary model, we find that addition of the chelate peptide, to form 26-10-1 sFv', does not alter the antigen-binding affinity of sFv. We have demonstrated nearly quantitative chelation of 0.5-50 mCi of 99mTc per mg of 26-10-1 sFv' (1 Ci = 37 GBq). These 99mTc-labeled sFv' complexes are highly stable to challenge with saline buffers, plasma, or diethylenetriaminepentaacetic acid. We find that the 99mTc-labeled 741F8-1 sFv', specific for the c-erbB-2 tumor-associated antigen, is effective in imaging human ovarian carcinoma in a scid mouse tumor xenograft model. This fusion chelate methodology should be applicable to diagnostic imaging with 99mTc and radioimmunotherapy with 186Re or 188Re, and its use could extend beyond the sFv' to other engineered antibodies, recombinant proteins, and synthetic peptides.
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