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ABSTRACT
Cultured chicken hepatocytes were used to investigate whether insulin and GH interact to regulate insulin-like growth factor-I (IGF-I) production in vitro. In the first set of experiments hepatocytes were preincubated for 6 h in hormone-free medium, and the effects of various combinations of insulin and GH on IGF-I production over the next 24 h were quantified by radioimmunoassay. Basal IGF-I production was 5·36 pg IGF-I/μg DNA and this was increased 1·31±0·13-fold (mean ± s.e.m.) by insulin, 1·90±0·24-fold by GH and 4·46±0·68-fold by a combination of insulin and GH. These results demonstrate that insulin and GH interact synergistically to stimulate IGF-I production in vitro. The synergism with GH occurred at physiological concentrations of insulin with half-maximal stimulation occurring at an insulin concentration of 6 ng/ml. In hepatocytes which had been exposed to insulin immediately before the start of the experiment, the presence of insulin was no longer required for maximal stimulation of IGF-I production by GH. This in-vitro system will facilitate the study of the molecular basis of the interaction between insulin and GH.
Journal of Endocrinology (1991) 128, 389–393
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ABSTRACT
The chicken pituitary gland contains a number of naturally occurring, developmentally regulated forms of GH which have identical molecular weights but differ in their isoelectric points. In order to characterize their biological properties, each must be separated from non-GH proteins and other forms of GH. Chicken GH (cGH) was separated from other pituitary proteins by immunoaffinity chromatography using an anti-GH monoclonal antibody covalently linked to Sepharose 4B. The cGH eluted from this column as a single peak and migrated as a single band during sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE), but showed multiple bands on isoelectric focussing. This material was chromatographed on a high-performance cation exchange column, and separation of charge isomers was monitored by a combination of isoelectric focussing and immunoblotting. Chicken GH eluted from this column in two distinct peaks. The minor peak (cGH P1) contained an isomer with an isoelectric point of 6·86 and the major peak (cGH P2) an isomer with an isoelectric point of 7·52. Each isomer migrated as a single band during isoelectric focussing and SDS-PAGE (M r = 23 500), and as a single peak during high-performance gel permeation chromatography and reverse-phase high-performance liquid chromatography. Analysis of cGH P2 through 30 cycles in a gas-phase microsequencer gave an amino acid sequence identical to that predicted by translation of the GH complementary DNA nucleotide sequence.
This single charge isomer increased the rate of lipolysis in chicken adipose tissue explants by about fourfold and was able to displace 125I-labelled cGH from binding sites in liver membranes with a dissociation constant of about 4 nmol/l. The output of insulin-like growth factor-I by hepatocytes in culture was increased from a basal rate of 50·4±11·6 (mean ± s.e.m.) to 787·9 ± 98·6 pg/6 × 106 cells per 48 h by two separate pulses of 1 μg cGH P2/ml. An i.v. injection of cGH P2 (15 μg/kg body weight) decreased the thyroxine:tri-iodothyronine ratio in serum of adult hens from 15·71 to 4·44, indicating an increase in 5′-monodeiodinase activity. These results demonstrate that the single most abundant charge isomer of chicken pituitary GH is likely to contain all the biological activity ascribed to the hormone.
Journal of Endocrinology (1990) 125, 207–215