Synonymous Codons and Hydrophobicity Optimization of Post-translational Signal Peptide PelB Increase Phage Display Efficiency of DARPins

DsbA leader peptide targets proteins for cotranslational translocation by signal recognition particle (SRP) pathway and has been the standard signal sequence for filamentous phage display of fast-folding Designed Ankyrin Repeat Proteins (DARPins). In contrast, translocation of DARPins via the post-translational pathway, for example, with the commonly used PelB leader, has been reported to be highly inefficient. In this study, two PelB signal sequence libraries were screened covering different regions of the leader peptide for identifying mutants with improved display of DARPins on phage. A PelB variant with the most favorable combination of synonymous mutations in the n-region and hydrophobic substitutions in the h-region increased the display efficiency of a DARPin library 44- and 12-fold compared to PelBWT and DsbA, respectively. Based on thioredoxin-1 (TrxA) export studies the triple valine mutant PelB DN5 V3 leader was capable of more efficient cotranslational translocation than PelBWT, but the overall display efficiency improvement over DsbA suggests that besides increased cotranslational translocation other factors contribute to the observed enhancement in DARPin display efficiency

Sensitive Luminometric Method for Protein Quantification in Bacterial Cell Lysate Based on Particle Adsorption and Dissociation of Chelated Europium

A sensitive and rapid assay for the quantification of proteins, based on sample protein adsorption to Eu³⁺-chelate-labeled nanoparticles, was developed. The lanthanide ion of the surface-conjugated Eu³⁺ chelate is dissociated at a low pH, decreasing the luminescence signal. The increased concentration of the sample protein prevents dissociation of the chelate, leading to a high luminescence signal due to the nanoparticle-bound protein. The assay sensitivity for the quantification of proteins was 130 pg for bovine serum albumin (BSA), which is an improvement of nearly 100-fold from the most sensitive commercial methods. The average coefficient of variation for the assay of BSA was 8%. The protein-to-protein variability was sufficiently low; the signal values varied within a 28% coefficient of variation for nine different proteins. The developed method is relatively insensitive to the presence of contaminants, such as nonionic detergents commonly found in biological samples. The existing methods tested for the total protein quantification failed to measure protein concentration in the presence of bacterial cell lysate. The developed method quantified protein also in samples containing insoluble cell components reducing the need for additional centrifugal assay steps and making the concept highly attractive for routine laboratory work