Expression of biologically active human thyrotropin (hTSH) in a baculovirus system: effect of insect cell glycosylation on hTSH activity in vitro and in vivo.

To obtain large amounts of hTSH and to study the role of the N-linked oligosaccharides for its biological activity, hTSH was produced using recombinant baculovirus containing the human alpha-subunit and a hTSH beta-minigene, respectively, both under the control of the polyhedrin promoter. Expression in insect cells was 800-1000 ng/ml, 30-fold higher than in our optimized mammalian transient transfection system using Chinese hamster ovary (CHO) cells (20-50 ng/ml). The in vitro activity of insect-cell expressed hTSH (IC-hTSH) was increased 5-fold compared with CHO-hTSH, judged by the ability to induce cAMP production in CHO cells stably transfected with the hTSH receptor (JP09) and the rat thyroid cell line FRTL-5, as well as growth promotion in FRTL-5 cells. Lectin binding and enzymatic desialylation studies suggested that in contrast to CHO-hTSH, IC-hTSH lacked complex-type oligosaccharides terminating with sialic acid but contained predominantly high mannose-type oligosaccharides. The in vitro activity of CHO-hTSH also increased 5- to 6-fold upon treatment of the hTSH-producing cells with the oligosaccharide processing inhibitors swainsonine and castanospermine, which inhibit formation of complex, terminally sialylated oligosaccharides, and upon enzymatic desialylation. In contrast, insect cell-expression or treatment with processing inhibitors did not affect TSH receptor binding. Despite the higher in vitro activity, IC-hTSH had a much lower in vivo activity than CHO-hTSH, due to rapid clearance from the circulation. In summary, this study shows for the first time that relatively high levels of recombinant hTSH with high in vitro bioactivity can be produced in a baculovirus system. Cell-dependent glycosylation is a major factor that determines the final in vivo biopotency of recombinant glycoproteins, a finding that should be of general relevance for all insect cell-produced glycosylated proteins. Although not suitable for clinical use, highly bioactive recombinant hTSH derived from high expression in insect cells should be useful in defining structure-function relations of hormone analogs.

A novel, nonradioactive in vivo bioassay of thyrotropin (TSH).

A new and simple in vivo bioassay suitable for routine testing of pituitary and recombinant TSH preparations was developed. Male Albino Swiss CF-1 mice were given T3 in their drinking water to suppress endogenous TSH. T3, 3.0 micrograms/mL, given to mice for a period of 4 days decreased plasma total T4 (TT4) level to less than 10% of the nonsuppressed (control) level. Various doses of exogenous pituitary and recombinant TSH preparations were injected intraperitoneally and blood samples were obtained from the orbital sinus 6 h later. The TT4 level, measured by radioimmunoassay, served as the assay end-point. The assay required injection of approximately 3.0 micrograms of pituitary human TSH (phTSH), 1.0 microgram recombinant human TSH (rhTSH), 0.2 microgram bovine TSH (bTSH), and 0.1 microgram rat TSH (rTSH) to attain half-maximal response. The maximal level of TT4 after TSH stimulation was similar to that observed in normal, nonsuppressed mice. The procedure developed is relatively easy to perform, economical, and, unlike earlier TSH bioassays, does not require the use of radionuclides. This bioassay showed acceptable sensitivity and reliability in structure-function studies of pituitary TSH from different species as well as rhTSH.

Purification and characterization of recombinant human thyrotropin (TSH) isoforms produced by Chinese hamster ovary cells: the role of sialylation and sulfation in TSH bioactivity.

The biological significance of glycosylation variants of pituitary glycoprotein hormones remains controversial because of the indirect methods usually employed to determine carbohydrate composition or structure as well as the use of unreliable biological/immunological ratio to determine bioactivity. We have previously characterized recombinant human TSH (rhTSH) secreted by Chinese hamster ovary cells attached to microcarrier beads in a large scale bioreactor after stable transfection of hCG alpha and hTSH beta minigenes. In the present study rhTSH has been used as a model to determine structure-function relationships of different isoforms of glycoprotein hormones. We have now produced greater than 200 mg rhTSH using a hollow fiber bioreactor. The highly purified rhTSH produced in the hollow fiber bioreactor (rhTSH-N) as well as rhTSH commercially produced in a large scale bioreactor (rhTSH-G) were quantitated by immunoassays, receptor binding assay, and amino acid analysis and further characterized by a variety of physico-biochemical methods, including chromatofocusing and carbohydrate analysis. rhTSH-G, rhTSH-N, as well as pituitary human TSH (phTSH) have been separated by chromatofocusing on a Mono P column into several isoforms with different pI values. Compositional analysis of the fractions showed higher sialic acid content in the more acidic rhTSH-G fractions. phTSH acidic isoforms showed higher total sulfate and sialic acid contents than the more basic fractions. The bioactivities of various TSH isoforms based on rigorous quantitation of mass by amino acid analysis determined in three different FRTL-5 cell bioassays showed that the more basic and less sialylated fractions of rhTSH-G were more active than the more acidic fractions. In contrast to the in vitro data, highly sialylated and acidic rhTSH-G isoforms showed longer plasma half-lives and higher in vivo bioactivity than the basic forms. These results indicate that secreted rhTSH, similar to intrapituitary phTSH, exists as a mixture of charge isoforms that are related at least in part to the degree of sialylation. The degree of sialylation, highly dependent on the bioreactor production conditions, appears to be the major factor affecting the charge heterogeneity, MCR, and bioactivity of rhTSH.

Regional and genotypic differences in stromal-vascular cells from obese and lean Zucker rats.

LPL activity, total lipogenesis and rates of growth were determined for stromal-vascular cells derived from epididymal and inguinal depots of 13 1/2-week-old obese and lean Zucker rats. LPL activity, in cells of both depots, was found to increase between days 4 and 6 and decrease by day 8 in the presence of insulin. Inguinal derived fatty cell LPL activity increased between days 4 and 8 in contrast to lean cells which peaked at day 6 under basal growth conditions. LPL activity was elevated in fatty versus lean cells at days 6 and 8 in inguinal derived stromal vascular cells while in epididymal derived stromal vascular cells, LPL activity was elevated in lean versus fatty derived cells at day 4 and 6 but by day 8 the genotypic effect was reversed. Lipogenesis was elevated in lean versus fatty derived epididymal and inguinal cells at all concentrations of insulin and lean cells showed a dose-dependent response to insulin in contrast to fatty cells. There were no effects of genotype on the proliferative capacity of cells from either depot but some regional differences in growth were observed. These data illustrate that fa gene effects can be studied in primary cell culture.