Abstract
BackgroundSite-specific protein labeling or modification can facilitate the characterization of proteins with respect to their structure, folding, and interaction with other proteins. However, current methods of site-specific protein labeling are few and with limitations, therefore new methods are needed to satisfy the increasing need and sophistications of protein labeling.MethodologyA method of protein C-terminal labeling was developed using a non-canonical split-intein, through an intein-catalyzed trans-splicing reaction between a protein and a small synthetic peptide carrying the desired labeling groups. As demonstrations of this method, three different proteins were efficiently labeled at their C-termini with two different labels (fluorescein and biotin) either in solution or on a solid surface, and a transferrin receptor protein was labeled on the membrane surface of live mammalian cells. Protein biotinylation and immobilization on a streptavidin-coated surface were also achieved in a cell lysate without prior purification of the target protein.ConclusionsWe have produced a method of site-specific labeling or modification at the C-termini of recombinant proteins. This method compares favorably with previous protein labeling methods and has several unique advantages. It is expected to have many potential applications in protein engineering and research, which include fluorescent labeling for monitoring protein folding, location, and trafficking in cells, and biotinylation for protein immobilization on streptavidin-coated surfaces including protein microchips. The types of chemical labeling may be limited only by the ability of chemical synthesis to produce the small C-intein peptide containing the desired chemical groups.
Highlights
Proteomics has become one of the fastest growing fields in life science research, and the demand for tools to analyze proteins has increased substantially
We have produced a method of site-specific labeling or modification at the C-termini of recombinant proteins
The short linker begins with a nucleophilic amino acid residue (Serine in this case) required for the splicing reaction
Summary
Proteomics has become one of the fastest growing fields in life science research, and the demand for tools to analyze proteins has increased substantially. Labeling a protein with a chemical entity, such as a fluorescent group, can facilitate protein characterization with respect to the protein’s three-dimensional structure, folding behavior, and interaction with other proteins. Protein labeling and modification are invaluable tools of protein engineering and extremely useful throughout life science, a major challenge is the addition of a chemical label or moiety sitespecifically to a protein. One chemical method can target the N-terminus of a protein [1], it requires the N-terminus to be solvent-exposed and depends on the nature of the N-terminal amino acid side chain. Site-specific protein labeling or modification can facilitate the characterization of proteins with respect to their structure, folding, and interaction with other proteins. Current methods of site-specific protein labeling are few and with limitations, new methods are needed to satisfy the increasing need and sophistications of protein labeling
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