Refolding of G protein alpha subunits from inclusion bodies expressed in Escherichia coli

Heterotrimeric G proteins relay signals from G protein-coupled receptors (GPCRs) to the interior of the cell. The signaling cascades induced by G protein activation control a wide range of cellular processes. The α subunit is believed to determine which G protein couples to each GPCR, and is the primary determinant of the type of signal transmitted. Several members of the G_α family have been expressed in active form in Escherichia coli. However, production levels of these proteins are limited: in most cases only 10% of total G_α protein expressed is active; the rest accumulates in inclusion bodies. Although G_iα has been readily expressed in soluble form (to 10 mg/L), other α subunits are minimally soluble, and many are exclusively expressed to inclusion bodies. Previous efforts to solubilize and refold G_α from inclusion bodies have not been successful. Here we did a thorough study of the characteristics of G_α subunits (human G_iα(1), human G_sα(short), human G_11α and human G_tα(cone)), solubilized and purified from inclusion bodies. We find that we can obtain soluble protein both by on-column and rapid-dilution techniques. Comparison to native, soluble G_iα expressed from E. coli showed that although the refolded G_α subunits were soluble and retained partial α-helicity characteristic of the native, folded G_α subunit, they did not bind GDP or GTP as effectively as native protein. We conclude that the refolded G_iα protein has a native-like secondary structure, but is predominately in a molten globular state.