Genetic construction, expression, and characterization of a single chain anti-carcinoma antibody fused to beta-lactamase.

We report the genetic construction and expression of a fusion protein between an antibody single chain-linked variable domain fragment specific for human carcinomas and beta-lactamase II from Bacillus cereus. Sequences encoding the variable regions of the L6 monoclonal antibody were assembled so as to be separated from each other by an 18-amino acid linker and from the mature form of beta-lactamase by a 6-amino acid linker. The construct was placed under the transcriptional regulation of the lac promoter, and the PelB signal sequence was used to direct export of the fusion protein to the periplasmic space of Escherichia coli. After induction, biologically active material was recovered from both culture supernatants and cell lysates. Affinity chromatography yielded about 2.5 micrograms of protein/ml of initial culture volume. The fusion protein was shown to bind to tumor cells at least as well as chemically prepared F(ab') and to maintain beta-lactamase activity at a level similar to that of the native enzyme. Tumor cells coated with the fusion protein were sensitive to a cephalosporin mustard prodrug in a dose-dependent fashion comparable to that of enzyme chemically conjugated to F(ab'). This article demonstrates the feasibility of using single chain-linked variable domain-enzyme fusion proteins for the activation of anticancer prodrugs.

Molecular modeling and preclinical evaluation of the humanized NR-LU-13 antibody.

A mouse-human chimeric monoclonal antibody (chNR-LU-13), specific for the EGP40 pancarcinoma antigen, was humanized through three-dimensional molecular modeling. Humanization of the chNR-LU-13 antibody is expected to enhance its use for patients undergoing immunotherapy. On the basis of the observed amino acid sequence identity, chNR-LU-13 complementary determining regions (CDRs) of the V(L) and V(H) regions were grafted onto the human anti-DNA-associated idiotype immunoglobulin clone, R3.5H5G'CL. Ten amino acids residues within the humanized framework were back-mutated to their corresponding chNR-LU-13 sequence, because they were predicted to disrupt the canonical classification of the CDRs or were within 5 A of a CDR. Synthesis of the V(L) and V(H) regions was accomplished by recursive PCR, and the dual-chain expression vector p451.C4 was positioned under control of the CMV(P+E). We observed by competitive ELISA that the recombinant humanized NR-LU-13 (huNR-LU-13) IgG1 antibody exhibited an indistinguishable immunoreactivity profile when compared with the murine monoclonal antibody (muNR-LU-10). The huNR-LU-13 antibody was effective in mediating both antibody-dependent cellular cytotoxicity and complement-mediated cytotoxicity when assayed against either the breast carcinoma cell line, MCF-7, or the colon adenocarcinoma cell line, SW1222. Biodistribution studies using i.v. coinjected 131I-muNR-LU-10 and 125I-huNR-LU-13 confirmed that the huNR-LU-13 specifically targets to the tumor in athymic BALB/c mice bearing the SW1222 human tumor xenograft. Humanization of the chNR-LU-13 antibody is expected to eliminate an undesired human antimouse antibody response, allowing for repeated i.v. administration into humans.

Nucleotide sequence of streptococcal pyrogenic exotoxin type C.

The nucleotide sequence of the gene speC, encoding streptococcal pyrogenic exotoxin type C (SPE C), was determined. The gene encoded a mature protein of 208 amino acids, with a calculated molecular weight of 24,354. The mature amino acid sequence of SPE C was analyzed for homology with the amino acid sequences of streptococcal pyrogenic exotoxin type A, the staphylococcal enterotoxins, and toxic shock syndrome toxin-1. Of these, SPE C shared the greatest amount of homology with streptococcal exotoxin type A.

Bacteriophage association of streptococcal pyrogenic exotoxin type C.

A gene encoding streptococcal pyrogenic exotoxin type C (SPE C) was isolated from bacteriophage DNA derived from Streptococcus pyogenes CS112. The gene, designated speC2, was shown to reside near the phage attachment site of phage CS112. A restriction endonuclease map of the CS112 phage was generated, and the location and orientation of the speC2 gene were determined. Hybridization analyses of eight SPE C-producing strains revealed restriction fragment length polymorphism of the speC gene-containing DNA fragments and further showed that each speC was linked to a common CS112 phage-derived DNA fragment.

Cloning and characterization of the gene, speC, for pyrogenic exotoxin type C from Streptococcus pyogenes.

The structural gene of streptococcal pyrogenic exotoxin type C (SPE C) was cloned from the chromosome of Streptococcus pyogenes strain T18P into Escherichia coli using pBR328 as the vector plasmid. Subcloning enabled the localization of the gene (speC) to a 1.7 kb fragment. Partially purified E. coli-derived SPE C and purified streptococcal-derived SPE C, were shown to have the same molecular weight (23,800) and biological activities. A DNA probe, prepared from cloned speC, cross-hybridized with the structural genes of SPE A and SPE B indicating relatedness at the nucleotide level. The speC-derived probe also hybridized to a fragment of CS112 bacteriophage DNA containing the phage attachment site.

Common structural features among monoclonal antibodies binding the same antigenic region of cytochrome c.

To examine if there are common physicochemical features among antibodies binding the same antigenic region of a protein, B cell hybridomas were prepared against the two major antigenic regions on mammalian cytochromes c, and the nucleotide sequences encoding the monoclonal antibody (mAb) heavy (H) and light (L) chains were determined and compared. Although the genetic elements used were somewhat diverse, similarities among mAbs to a given antigenic region were observed. In particular, mAbs binding in a region situated at a bend in the antigen around residues 44 and 47 had longer complementarity-determining regions (4-5 additional amino acid residues in L1 and 1-2 in H3) than mAbs binding the other region around residues 60 and 62 located on a relatively flat surface. These observations indicate that the topography of an antigenic site and the lengths of certain complementarity-determining regions are important physicochemical properties determining, at least in part, which antibodies (B cells) will participate in an immune response to a particular site on a protein antigen.

Bacterial aspects associated with the expression of a single-chain antibody fragment in Escherichia coli.

The bacterial expression of a single-chain antibody fragment, designated L6 sFv, was examined. Periplasmic targeting resulted in the production of a correctly folded protein that bound tumor antigen. However, immediately after induction at either 30 degrees C or 37 degrees C there was a significant loss in bacterial viability, which was followed by a loss in absorbance. The loss in absorbance correlated with cell lysis and release of the L6 sFv into the culture supernatant. The kinetics of appearance of L6 sFv in the supernatant paralleled that of periplasmic beta-lactamase and confirmed an initial loss of cell-wall integrity prior to cell lysis. Bacteria incubated at 30 degrees C produced approximately threefold more correctly folded antibody fragment because of an increase in the number of cells/A660 at the lower incubation temperature. More than 95% of the L6 sFv, made at either incubation temperature, was incorrectly folded. Osmotic-shock procedures did not release L6 sFv. However, in situ subtilisin susceptibility experiments with bacterial spheroplasts confirmed a periplasmic location. French press disruption resulted in the release of correctly but not incorrectly folded material. Membrane fractionation revealed that the incorrectly folded L6 sFv remained associated with both the inner and outer membrane. These results demonstrate that, in this system, antibody fragment expression resulted initially in cell death, which was followed by release of protein into the culture supernatant and eventually cell lysis. It is also suggested that membrane association in the periplasmic space may impede proper folding.