Adsorption studies of tritium-labeled peptides on polystyrene surfaces.

In this study, three presentation formats of an epitope peptide (hepta-peptide), derived from the human chorionic gonadotropin amino acid sequence, were compared for adsorption to the polystyrene wells of a microELISA plate. The peptides had either a free N-terminus, an Ata-group or a linear (Lys)7-extension at the N-terminal. In order to measure the adsorption properties, all peptides were tritiated by synthesizing an additional 3H-labeled glycyl residue to the N-terminus of their peptide sequence. Over a broad range of peptide concentrations used as coat solution, extension of the peptide by an Ata-group consistently increased adsorption by a factor of 1.5 to 3 compared to the free parent peptide. Of the three peptides studied, the Ata-peptide showed the highest surface coverage of 0.6 mg/m2 when 1.0 mmol/l was offered as the concentration of peptide in the coating solution. The highest surface coverage observed for the parent peptide was 0.4 mg/m2 (at 1.5 mmol/l). The lysyl (K7) peptide showed a maximum plateau value of 0.2 mg/m2, and therefore the lysyl (K7) extension reduced the peptide surface coverage at relatively high coat concentrations (above 0.1 mmol/l) compared to the parent peptide. At lower input concentrations (below 0.1 micromol/l), however, the packing density of the lysyl (K7) peptide was up to 25 times higher when compared to the other two peptide analogs. We conclude that better adsorption as well as improved antibody binding activity and (functional) affinity could explain the higher reactivity observed in ELISA procedures when peptides are N-terminally extended by an Ata-group or lysyl (K7) extension.

Direct coating of poly(lys) or acetyl-thio-acetyl peptides to polystyrene: the effects in an enzyme-linked immunosorbent assay.

Direct adsorption of small peptides to polystyrene surfaces is often not satisfactory. Therefore, a simple and general coating procedure to improve the coating efficiency of small synthetic peptide antigens to polystyrene is described. In this study, the binding capacities of four small synthetic peptides N-terminally linked to various moieties during synthesis were compared to their parent counterparts in terms of the amount of peptide coat concentration required to achieve 50% of the maximum enzyme-linked immunosorbent assay signal. Elongation of a short epitope sequence by an N-terminal acetyl-thio-acetyl (Ata) group or a lysyl moiety resulted in an enormous reduction in peptide coat concentration for all tested peptides of net two to four orders of magnitude when corrected for chain elongation. The optimal length of the lysyl moiety depended on the length of the model peptide. Replacement of both extensions by analogues (i.e., Ata analogues and other basic amino acid residues in the case of the lysyl moiety) was possible without reducing their enhancing properties to a great extent. Additional experiments showed that a lysyl moiety consisting of a linear stretch of seven lysyl moiety consisting of a linear stretch of seven lysyl residues was more effective in comparison to a branched lysyl construct and could easily compete with the multiple antigen peptide approach.