Abstract
Affinity chromatography is the linchpin of antibody downstream processing and typically relies on bacterial immunoglobulin (Ig)-binding proteins, epitomized by staphylococcal protein A-based ligands. However, such affinity ligands are fairly costly and suffer from chemical instability, leading to ligand denaturation and leaching from chromatographic support. Innovations in this area are aimed at developing robust and highly selective antibody ligands capable of withstanding harsh column sanitization conditions. We report the development and first-stage characterization of a selective short linear peptide ligand of the IgG Fc region capable of capturing all four IgG subclasses. The ligand was discovered through in vitro directed evolution. A focused phage-display library based on a previously identified peptide lead was subjected to a single-round screen against a pool of human IgG. The hits were identified with next-generation sequencing and ranked according to the enrichment ratio relative to their frequency in the pre-screened library. The top enriched peptide GSYWYNVWF displaying highest affinity for IgG was coupled to bromohydrin-activated agarose beads via a branched linker. The resulting affinity matrix was characterized with a dynamic binding capacity of approx. 43 mg/mL, on par with commercially employed protein A-based resin.
Highlights
Affinity chromatography is the linchpin of antibody downstream processing and typically relies on bacterial immunoglobulin (Ig)-binding proteins, epitomized by staphylococcal protein A-based ligands
We show that the optimized peptide-functionalized affinity matrix displays dynamic binding capacity that is comparable to the spA-based commercial one, and facilitates isolation of human IgGs of all four subclasses
While affinity chromatography based on bacterial immunoglobulin-binding proteins, such as staphylococcal protein A, still represents the cornerstone of antibody isolation and purification, it is associated with high operational costs due to ligand instability
Summary
Affinity chromatography is the linchpin of antibody downstream processing and typically relies on bacterial immunoglobulin (Ig)-binding proteins, epitomized by staphylococcal protein A-based ligands Such affinity ligands are fairly costly and suffer from chemical instability, leading to ligand denaturation and leaching from chromatographic support. Isotype G immunoglobulins (IgGs) are widely used as biorecognition reagents in basic molecular biology research and diagnostics[1], including enzyme-linked immunosorbent assay (ELISA), western blot, immunocytochemistry, fluorescence-activated cell sorting, immunoprecipitation, and for selective capture of analytes in biosensor detection/quantification They are distinguished by high affinity, owing to the preorganized conformation of highly specific complementarity-determining region loops that interact with an antigen. Coupled to paramagnetic beads or cross-linked agarose matrix, the optimized peptide ligand min19Fc-Q6D (GSYWYDVWF) was shown to selectively enrich antibodies from complex protein mixtures in pull-down assays and affinity chromatography
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