Single‐step electrotransfer of reverse‐stained proteins from sodium dodecyl sulfate‐polyacrylamide gel onto reversed‐phase minicartridge and subsequent desalting and elution with a conventional high‐performance liquid chromatography gradient system for analysis

Isolation of proteins from polyacrylamide electrophoresis gels by a novel combination of techniques is described. A given protein band from a reverse stained (imidazol‐sodium dodecyl sulfate – zinc salts) gel can be directly electrotransferred onto a reversed‐phase chromatographic support, packed in a self‐made minicartridge (2 mm in thickness, 8 mm in internal diameter, made of inert polymeric materials). The minicartridge is then connected to a high‐performance liquid chromatography system and the electrotransferred protein eluted by applying an acetonitrile gradient. Proteins elute in a small volume (> 700 μL) of high‐purity volatile solvents (water, trifluoroacetic acid, acetonitrile) and are free of contaminants (gel contaminants, salts, etc). Electrotransferred proteins were efficiently retained, e.g. , up to 90% for radioiodinated α‐lactalbumin, by the octadecyl matrix, and their recovery on elution from the minicartridge was in the range typical for this type of chromatographic support, e.g. , 73% for α‐lactalbumin. The technique was successfully applied to a variety of proteins in the molecular mass range 6–68 kDa, and with amounts between 50 and 2000 pmol. The good mechanical and chemical stability of the developed minicartridges, during electrotransfer and chromatography, allowed their repeated use. This new technique permitted a single‐step separation of two proteins unresolved by sodium dodecyl sulfate‐polyacrylamide gel electrophoresis due to their different elution from the reversed‐phase support. The isolated proteins were amenable to analysis by N ‐terminal sequencing, enzymic digestion and mass spectrometry of their proteolytic fragments. Chromatographic elution of proteins from the reversed‐phase mini‐cartridge was apparently independent of the specific loading mode employed, i.e. , loading by conventional loop injection or by electrotransfer.