Pharmacological applications of a novel neoepitope antibody to a modified amyloid precursor protein-derived beta-secretase product.

We have previously described a novel artificial NFEV ß-secretase (BACE1) cleavage site, which when introduced into the amyloid-ß precursor protein (APP), significantly enhances APP cleavage by BACE1 in in vitro and cellular assays. In this study, we describe the identification and characterization of a single chain fragment of variable region (scFv), specific to the EV neo-epitope derived from BACE1 cleavage of the NFEV-containing peptide, and its conversion to IgG1. Both the scFv displayed on phage and EV-IgG1 show exquisite specificity for binding to the EV neoepitope without cross-reactivity to other NFEV containing peptides or WT-APP KMDA cleavage products. EV-IgG1 can detect as little as 0.3 nmol/L of the EV peptide. EV-IgG1 antibody was purified, conjugated with alkaline phosphatase and utilized in various biological assays. In the BACE1 enzymatic assay using NFEV substrate, a BACE1 inhibitor MRK-3 inhibited cleavage with an IC(50) of 2.4 nmol/L with excellent reproducibility. In an APP_NFEV stable SH-SY5Y cellular assay, the EC(50) for inhibition of EV-Aß peptide secretion with MRK-3 was 236 nmol/L, consistent with values derived using an EV polyclonal antibody. In an APP_NFEV knock-in mouse model, both Aß_EV40 and Aß_EV42 peptides in brain homogenate showed excellent gene dosage dependence. In conclusion, the EV neoepitope specific monoclonal antibody is a novel reagent for BACE1 inhibitor discovery for both in vitro, cellular screening assays and in vivo biochemical studies. The methods described herein are generally applicable to novel synthetic substrates and enzyme targets to enable robust screening platforms for enzyme inhibitors.

Affinity maturation and characterization of a human monoclonal antibody against HIV-1 gp41.

The human D5 monoclonal antibody binds to the highly conserved hydrophobic pocket on the N-terminal heptad repeat (NHR) trimer of HIV-1 gp41 and exhibits modest yet relatively broad neutralization activity. Both binding and neutralization depend on residues in the complementarity determining regions (CDRs) of the D5 IgG variable domains on heavy chain (VH) and light chain (VL). In an effort to increase neutralization activity to a wider range of HIV-1 strains, we have affinity matured the parental D5 scFv by randomizing selected residues in 5 of its 6 CDRs. The resulting scFv variants derived from four different CDR changes showed enhanced binding affinities to gp41 NHR mimetic (5-helix) which correlated to improved neutralization potencies by up to 8-fold. However, when converted to IgG1s, these D5 variants had up to a 12-fold reduction in neutralization potency over their corresponding scFvs despite their slightly enhanced in vitro binding affinities. Remarkably, D5 variant IgG1s bearing residue changes in CDRs that interact with epitope residues N-terminal to the hydrophobic pocket (such as VH CDR3 and VL CDR3) retained more neutralization potency than those containing residue changes in pocket-interacting CDRs (such as VH CDR2). These results provide compelling evidence for the existence of a steric block to an IgG that extends to the gp41 NHR hydrophobic pocket region, and can be a useful guide for developing therapeutic antibodies and vaccines circumventing this block.

Short communication: In vitro synergy between peptides or neutralizing antibodies targeting the N- and C-terminal heptad repeats of HIV Type 1 gp41.

Class 1 and class 2 fusion peptides bind to the trimeric N-terminal heptad repeat (NHR) and C-terminal heptad repeat (CHR) regions of HIV-1 envelope glycoprotein gp41, respectively, and block its intramolecular folding required for Env-mediated viral and host cell membrane fusion and subsequent viral entry. Using a combination of T-20 (class 1) and (CCIZN17)(3) (class 2), we provide evidence that these classes of fusion peptides work synergistically in an in vitro infectivity assay in inhibiting the entry of primary HIV-1 isolate 89.6 with combination indexes reaching 0.37 and 0.32 at IC(50) and IC(90), respectively. We further demonstrate a similar degree of neutralization synergy between a monoclonal antibody (MAb), D5, targeting the hydrophobic pocket region of the NHR, and 2F5, a well-characterized MAb that targets the C-terminal end of CHR and the membrane-proximal external region (MPER), providing a rational basis for developing combination vaccines targeting these two highly conserved regions of gp41.

Automated high-throughput purification of antibody fragments to facilitate evaluation in functional and kinetic based assays.

Screening antibodies from phage displayed in vitro libraries and from affinity maturation of lead antibodies requires testing of antibody fragments (scFvs and Fabs) for function and binding affinities. Crude scFv or Fab periplasmic preparations from Escherichia coli are often not pure and/or concentrated enough for use in functional and affinity assays. We have developed an automated high-throughput approach for small and large-scale expression and purification of His-tagged scFvs and Fabs using the Qiagen BioRobot 3000 LS with optimized application software. This automated procedure enabled us to rapidly evaluate antibody fragments in functional and surface plasmon resonance (SPR) assays. We have used these procedures to make thousands of purified scFv/Fabs for several antibody maturation campaigns and significantly decreased the time needed to select the best candidates. The assay results from these purified samples were used to prioritize candidates before converting them to IgG. This protocol can process up to 300 small-scale and up to 72 large-scale scFvs or Fabs per week per full-time employee (FTE).

Design of plasmid DNA constructs for vaccines.

For more than three decades, plasmids have been widely used in the biotechnology arena. Historically, they have been most often employed for the expression of heterologous proteins in a variety of microorganisms. More recently, plasmids have been used as vectors for the delivery of antigen encoding genes in order to elicit immune responses in higher order animals. In this chapter, we discuss methods for constructing vectors with this unique purpose. Considerations for choosing the replicon, antigen, expression elements, and host cells are discussed within the context of developing a commercially viable vaccine vector.