High-Throughput Protein Expression Screening of Cell-Surface Protein Ectodomains.

Cell-surface receptors can be difficult to express and purify for structural and biochemical studies due to low expression levels, misfolding, aggregation, and instability. Cell-surface receptor ectodomains are more amenable to large-scale production, but this requires designing and testing various truncation constructs. However, since each protein is unique, testing these constructs individually for many targets is a time-consuming process. In this context, we present a high-throughput ELISA fluorescence approach that allows the rapid assessment of numerous recombinant constructs simultaneously. Cell-surface ectodomains are expressed in small scale, enzymatically biotinylated, and detected using a C-terminal His-tag. As an example, we tested the expression of truncation constructs for the neurexin, neuroligin, and latrophilin families and show that the small-scale ELISA allowed us to prioritize well-expressing construct for large-scale production. By employing this method, one can efficiently detect clones with low expression levels, streamlining the process and saving valuable time in identifying optimal candidates for further study.

Development of an efficient signal amplification strategy for label-free enzyme immunoassay using two site-specific biotinylated recombinant proteins.

Constructing a recombinant protein between a reporter enzyme and a detector protein to produce a homogeneous immunological reagent is advantageous over random chemical conjugation. However, the approach hardly recombines multiple enzymes in a difunctional fusion protein, which results in insufficient amplification of the enzymatic signal, thereby limiting its application in further enhancement of analytical signal. In this study, two site-specific biotinylated recombinant proteins, namely, divalent biotinylated alkaline phosphatase (AP) and monovalent biotinylated ZZ domain, were produced by employing the Avitag-BirA system. Through the high streptavidin (SA)-biotin interaction, the divalent biotinylated APs were clustered in the SA-biotin complex and then incorporated with the biotinylated ZZ. This incorporation results in the formation of a functional macromolecule that involves numerous APs, thereby enhancing the enzymatic signal, and in the production of several ZZ molecules for the interaction with immunoglobulin G (IgG) antibody. The advantage of this signal amplification strategy is demonstrated through ELISA, in which the analytical signal was substantially enhanced, with a 32-fold increase in the detection sensitivity compared with the ZZ-AP fusion protein approach. The proposed immunoassay without chemical modification can be an alternative strategy to enhance the analytical signals in various applications involving immunosensors and diagnostic chips, given that the label-free IgG antibody is suitable for the ZZ protein.