The influence of the framework core residues on the biophysical properties of immunoglobulin heavy chain variable domains

Antibody variable domains differ considerably in stability. Single-chain Fv (scFv) fragments derived from natural repertoires frequently lack the high stability needed for therapeutic application, necessitating reengineering not only to humanize their sequence, but also to improve their biophysical properties. The human VH3 domain has been identified as having the best biophysical properties among human subtypes. However, complementarity determining region (CDR) grafts from highly divergent VH domains to huVH3 frequently fail to reach its superior stability. In previous experiments involving a CDR graft from a murine VH9 domain of very poor stability to huVH3, a hybrid VH framework was obtained which combines the lower core residues of muVH9 with the surface residues of huVH3. It resulted in a scFv with far better biophysical properties than the corresponding grafts to the consensus huVH3 framework. To better understand the origin of the superior properties of the hybrid framework, we constructed further hybrids, but now in the context of the consensus CDR-H1 and -H2 of the original human VH3 domain. The new hybrids included elements from either murine VH9, human VH1 or human VH5 domains. From guanidinium chloride-induced equilibrium denaturation measurements, kinetic denaturation experiments, measurements of heat-induced aggregation and comparison of soluble expression yield in Escherichia coli, we conclude that the optimal VH framework is CDR-dependent. The present work pinpoints structural features responsible for this dependency and helps to explain why the immune system uses more than one framework with different structural subtypes in framework 1 to optimally support widely different CDR

Affinity and folding properties both influence the selection of antibodies with the selectively infective phage (SIP) methodology

AbstractWe investigated which molecules are selected from a model library by the selectively infective phage (SIP) methodology. As a model system, we used the fluorescein binding single-chain Fv fragment FITC-E2, and from a 3D-model, we identified 11 residues potentially involved in hapten binding and mutated them individually to alanines. The binding constant of each mutant was determined by fluorescence titration, and each mutant was tested individually as well as in competitive SIP experiments for infectivity. After three rounds of SIP, only molecules with KD values within a factor of 2 of the tightest binder remain, and among those, a mutant no longer carrying an unnecessary exposed tryptophan residue is preferentially selected. SIP is shown to select for the best overall properties of the displayed molecules, including folding behavior, stability and affinity

Receptor-targeted lentiviral vectors are exceptionally sensitive toward the biophysical properties of the displayed single-chain Fv

An increasing number of applications require the expression of single-chain variable fragments (scFv) fusion proteins in mammalian cells at the cell surface membrane. Here we assessed the CD30-specific scFv HRS3, which is used in immunotherapy, for its ability to retarget lentiviral vectors (LVs) to CD30 and to mediate selective gene transfer into CD30-positive cells. Fused to the C-terminus of the type-II transmembrane protein hemagglutinin (H) of measles virus and expressed in LV packaging cells, gene transfer mediated by the released LV particles was inefficient. A series of point mutations in the scFv framework regions addressing its biophysical properties, which substantially improved production and increased the melting temperature without impairing its kinetic binding behavior to CD30, also improved the performance of LV particles. Gene transfer into CD30-positive cells increased ∼100-fold due to improved transport of the H-scFv protein to the plasma membrane. Concomitantly, LV particle aggregation and syncytia formation in packaging cells were substantially reduced. The data suggest that syncytia formation can be triggered by trans-cellular dimerization of H-scFv proteins displayed on adjacent cells. Taken together, we show that the biophysical properties of the targeting ligand have a decisive role for the gene transfer efficiency of receptor-targeted LV

Stabilization and humanization of a single-chain Fv antibody fragment specific for human lymphocyte antigen CD19 by designed point mutations and CDR-grafting onto a human framework

A single-chain Fv (scFv) fragment derived from the murine antibody 4G7, specific for human lymphocyte CD19, was engineered for stability and expression in Escherichia coli in view of future use as a therapeutic protein. We compared two orthogonal knowledge-based procedures. In one approach, we designed a mutant with 14 single amino-acid substitutions predicted to correct destabilizing residues in the 4G7-wt sequence to create 4G7-mut. In the second variant, the murine CDRs were grafted to the human acceptor framework huVκ3-huVH3, with 11 additional point mutations introduced to obtain a better match between CDR graft and acceptor framework, to arrive at 4G7-graft. Compared to 4G7-wt, 4G7-mut showed greater thermodynamic stability in guanidinium chloride-induced equilibrium denaturation experiments and somewhat greater stability in human serum. The loop graft maintained the comparatively high stability of the murine loop donor, but did not improve it further. Our analysis indicates that this is due to subtle strain introduced between CDRs and framework, mitigating the otherwise highly favorable properties of the human acceptor framework. This slight strain in the loop graft is also reflected in the binding affinities for CD19 on leukemic cells of 8.4 nM for 4G7-wt, 16.4 nM for 4G7-mut and 30.0 nM for 4G7-graft. This comparison of knowledge-based mutation and loop-grafting-based approaches will be important, when moving molecules forward to therapeutic application