Single-chain human follicle-stimulating hormone with a di-N-glycosylated linker

Abstract

The classic way to produce single-chain (sc) glycoprotein hormones is to fuse their two subunits through the carboxy-terminal peptide (CTP) from human Choriogonadotropin (hCG). The CTP confers a longer half-life to single-chain hormones thanks to its four O-glycosyl side chains. However, unlike syncytiotrophoblastic cells, most cells used for recombinant protein production do not transfer O-glycosyl chains efficiently. We thus choose to fuse the hFSH subunits with a linker comprising two N-glycosyl side chains (sc-hFSH LNN) or none (sc-hFSH L0N), that were generated using two expression systems, HEK293 and CHO K1 cells. Their production levels and biological activities were tested and compared. Both expression systems successfully produced biologically active sc-hFSH, but, in our hands, CHO K1 cells yielded about 30-fold higher amounts of recombinant protein than HEK293 cells. Moreover, sc-hFSH L0N was considerably less expressed than sc-hFSH LNN in both cell types. Our data show that sc-hFSH L0N and sc-hFSH LNN produced from both cell lines stimulate cAMP and progesterone production in mLTC cells expressing hFSH receptors and exhibit similar B/I (in vitro Bioactivity/Immuno activity) ratios. Finally, the ratio of in vivo/in vitro bioactivities for sc-hFSH LNN relative to natural pituitary heterodimeric hFSH increased 8-fold, most likely because of a longer half-life in the blood.