High level secretion of wild-type and mutant forms of human proapoA-I using baculovirus-mediated Sf-9 cell expression.

To facilitate the investigation of apoA-I structure:function relationships as they relate to LCAT activation and lipid binding, we have developed an apoA-I baculoviral expression and purification system that yields milligram quantities of wild-type or mutant proapoA-I. Baculovirus-infected Sf-9 cells, grown in suspension, were found to secrete high levels of human wild-type (40-50 mg/l) or mutant apoA-I protein (1-38 mg/l), which was determined to be > 95% pure following a two-step purification procedure. In the case of wild-type apoA-I, ELISA showed that approximately 13-18% of the total protein secreted into the culture medium was apoA-I. To isolate pure protein from culture medium, 72 h post-infection medium was subjected to preparative reverse phase high performance liquid chromatography (HPLC), followed by DEAE ion-exchange chromatography. Purity and molecular size determination of wild-type proapoA-I protein was verified by SDS polyacrylamide gel electrophoresis, electrospray mass spectrometry, and N-terminal sequencing. In addition, recombinant discoidal apoA-I:phospholipid complexes prepared from wild-type or plasma apoA-I showed similar particle size and LCAT activation properties. To fully characterize the utility of this expression system, the expression levels of various mutant apoA-I proteins were compared to wild-type. Despite a lower production level seen with selected apoA-I mutants, milligram quantities of these purified mutant proteins were also obtained. In summary, we show that baculovirus-derived wild-type proapoA-I shows properties similar to plasma apoA-I relative to recombinant HDL formation, LCAT reactivity, and alpha-helical content. In addition, we show that a variety of mutant forms of human proapoA-I can be expressed and purified in abundant quantity from baculoviral-infected Sf-9 cells.