Ex12 helper phage improves the quality of a phage-displayed antibody library by ameliorating the adverse effect of clonal variations.

The quality of a phage-displayed antibody library deteriorates with clonal variations, which are caused by differentially expressed Escherichia coli antibody genes. Using the human Fab SP114 against the pyruvate dehydrogenase complex-E2 (PDCE2), we created four E. coli TOP10F' clones with a pCMTG phagemid encoding Fab-pIII (pCMTG-Fab), Fd (V(H)+C(H1))-pIII (pCMTG-Fd), or light chain (L) (pCMTG-L), or the vector only (pCMTG-∆Fab) to investigate the effect of clonal variations in a defined manner. Compared to the others, the E. coli clone with pCMTG-Fab was growth retarded in liquid culture, but efficiently produced phage progenies by Ex12 helper phage superinfection. Our results suggest that an antibody library must be cultured for a short duration before helper phage superinfection, and that the Ex12 helper phage helped to alleviate the detrimental effect of clonal variation, at least in part, by preferentially increasing functional phage antibodies during phage amplification.

Isolation of human Fab antibodies specific for the low-affinity IgE receptor (CD23) by selecting a hierarchical antibody library system against B lymphoblastic IM-9 cells.

The development of human antibodies specific for certain B cell markers is required to generate therapeutic antibody leads with improved therapeutic indices against B-cell lymphomas. To meet this demand, we selected a primary human antibody library, HuDVFab-8L, against human B lymphoblastic IM-9 cells via a 'Biopanning and Rapid Analysis of Selective Interactive Ligands (BRASIL)' cell panning approach. Six Fab clones that specifically bound to IM-9 cells were successfully isolated. Among these clones, two clones (IM-L6-E and IM-L8-G), were found to be specific for CD23 (FcɛRII). Affinity maturation of these Fab clones was then performed in a hierarchical manner by constructing secondary antibody libraries through combining heavy (H) chains of two Fabs with the human kappa L chain sublibrary HuNL-D3 followed by biopanning against the CD23 antigen. Clone IM-L6-5, one of the affinity maturated Fab derivatives from IM-L6-E, has a binding affinity of k(D)≈30 nM to soluble CD23. In addition, IM-L6-5 Fab is able to bind to an inducible form of CD23 expressed on U937 cells upon IL-4 stimulation, and inhibits binding of human IgE to CD23. Since the Fab IM-L6-5 is derived from a fully human naïve origin, we believe that IM-L6-5 can be utilized for the development of a therapeutic mAb which may have an improved therapeutic index over lumiliximab, a primatized anti-CD23 mAb, for the treatment of CLL or allergic diseases.

Development of the dual-vector system-III (DVS-III), which facilitates affinity maturation of a Fab antibody via light chain shuffling.

Light (L) chain shuffling is routinely used to analyze optimal L chains that pair with a specific heavy (Fd or H) chain, which ultimately leads to in vitro affinity maturation of a particular antibody. One of the major drawbacks to this procedure is that L chain libraries have to be created for each distinct H chain, which involves complicated cloning procedures. Herein, we designed of the dual-vector system-III (DVS-III), which is composed of a set of pLf1T-3 phagemid and pHg3A-3 plasmid, for L chain shuffling of any given human Fab antibody via phage display technology. To demonstrate the feasibility of our system, a human naïve L chain sublibrary, HuNL-D3, constructed in pLf1T-3 phagemid, was combined with the Fd of a human anti-IL-15 Fab, 4H10, subcloned in pHg3A-3 plasmid as a model system. After solution-phase sorting and biopanning the library we obtained eight Fab variants (4H10-LP1-7 and 4H10-LS). Among them, 4H10-LP4 exhibited the highest affinity which is about 36-fold higher than that of the parent molecule 4H10 (K(D)=6 nM versus 200 nM). Our results demonstrate that the DVS-III, along with the HuNL-D3 L chain sublibrary, can be served as a convenient approach for affinity maturation of any given human Fab antibody through L chain optimization.

Methods for rapid identification of a functional single-chain variable fragment using alkaline phosphatase fusion.

The generation of functional recombinant antibodies from hybridomas is necessary for antibody engineering. However, this is not easily accomplished due to high levels of aberrant heavy and light chain mRNAs, which require a highly selective technology that has proven complicated and difficult to operate. Herein, we attempt to use an alkaline phosphate (AP)-fused form of single-chain variable fragment (scFv) for the simple identification of a hybridoma-derived, functional recombinant antibody. As a representative example, we cloned the scFv gene from a hybridoma-producing mouse IgG against branched-chain keto acid dehydrogenase complex-E2 (BCKD-E2) into an expression vector containing an in-frame phoA gene. Functional recombinant antibodies were easily identified by conventional enzyme-linked immunosorbent assay (ELISA) by employing scFv-AP fusion protein, which also readily serves as a valuable immuno-detective reagent.

Successful application of the dual-vector system II in creating a reliable phage-displayed combinatorial Fab library.

The dual-vector system-II (DVS-II), which allows efficient display of Fab antibodies on phage, has been reported previously, but its practical applicability in a phage-displayed antibody library has not been verified. To resolve this issue, we created two small combinatorial human Fab antibody libraries using the DVS-II, and isolation of target-specific antibodies was attempted. Biopanning of one antibody library, termed DVFAB-1L library, which has a 1.3 x 10(7) combinatorial antibody complexity, against fluorescein-BSA resulted in successful isolation of human Fab clones specific for the antigen despite the presence of only a single light chain in the library. By using the unique feature of the DVS-II, an antibody library of a larger size, named DVFAB-131L, which has a 1.5 x 10(9) combinatorial antibody complexity, was also generated in a rapid manner by combining 1.3 x 10(7) heavy chains and 131 light chains and more diverse anti-fluorescein-BSA Fab antibody clones were successfully obtained. Our results demonstrate that the DVS-II can be applied readily in creating phage-displayed antibody libraries with much less effort, and target-specific antibody clones can be isolated reliably via light chain promiscuity of antibody molecule.

Establishment of a reliable dual-vector system for the phage display of antibody fragments.

To resolve some of the technical limitations in a phage-displayed Fab library, we have designed two dual-vector systems, DVS-I and DVS-II, composed of a set of replicon-compatible plasmid (pLA-1 or pLT-2) for producing soluble L chain fragments and phagemid (pHf1g3T-1 or pHf1g3A-2) for expressing Fd (V(H)+C(H1))-DeltapIII fusion molecules as well as a genotype-phenotype linkage. Compared to the DVS-I (pLA-1 and pHf1g3T-1), the DVS-II (pLT-2 and pHf1g3A-2) showed stable transformation efficiency regardless of the order of the vectors introduced into the host cells. In addition, expression of soluble Fab molecules with antigen-binding reactivity, recombinant phage titer and display level of functional Fab-DeltapIII on the phage progenies of the DVS-II were comparable with a conventional phage display system using a single phagemid vector. More importantly, the phage displaying target-specific Fab-DeltapIII molecules was successfully enriched by panning, which allows isolation of the pHf1g3A-2 phagemid encoding antigen-specific Fd molecules. We believe that the DVS-II may provide a valuable tool in the construction of a combinatorial phage-displayed Fab library with large diversity. Furthermore, it can be readily applied to isolation of desired antibody clones if L chain promiscuity of antibodies in determining antigen-binding specificity is considered, or in guided-selection or chain shuffling of mAbs of non-human origin.