In earlier studies we have shown that insulin does not stimulate glucose incorporation in adipocytes of hypophysectomized (hypox) rats. Basal glucose incorporation is decreased, although basal 3-O-methylglycose transport is very rapid and cannot be further stimulated by insulin. In this study we treated hypox rats with human GH, ACTH, and T3, alone or in combination, and examined the effects of insulin on glucose incorporation into fat cells and on 3-O-methylglucose transport. The results show that chronic administration of T3 alone to hypox rats partially restores glucose incorporation into fat cells and, in combination with ACTH, completely restores this incorporation. The two hormones have no effect on the glucose carrier system. The transport rate under T3 and ACTH replacement therapy continues to proceed at a maximal rate, so that basal glucose incorporation is high but not further enhanced by insulin. In contrast, administration of human GH to hypox rats does not influence glucose incorporation but has a marked effect on glucose transport. The basal glucose transport rate returns toward normal and again responds to insulin. This suggests 1) that enzyme activities responsible for the lipogenetic capacity of the fat cell are decreased in hypox rats and returned toward normal by the combined T3/ACTH treatment, and 2) that the limitation of glucose transport in the fat cell is controlled by GH. GH seems to induce a change of the glucose-carrier system; it leads to a restriction of glucose transport, which is acutely modulated by insulin.
The concentration of mRNA of insulin-like growth factor-II is (IGF-II) much elevated in some embryonic tumours such as Wilms tumour (nephroblastoma). In order to prove whether or not IGF-II is produced by the tumour tissue, IGF-II was extracted from freshly frozen tissue of Wilms tumour and hepatoblastoma. Normal adjacent tissue of kidney and liver was used as a control. The total IGF-II in Wilms tumour was 548.4 +/- 77.4 ng/g (n = 7) compared to 112.8 +/- 38.2 ng/g (n = 5) in kidney. In two hepatoblastomas, it was 96.1 +/- 22.8 ng/g compared to 30.1 +/- 14.2 ng/g in normal liver. Small pieces of fresh primary tissue of several Wilms tumours were successfully transplanted into immunodeficient nude mice. In serum of tumour-bearing mice IGF-II was elevated compared to normal mice. Liver weight of tumour bearing mice was higher than that of control mice (2.29 +/- 0.4 g and 2.02 +/- 0.06 g; P < 0.005). This was also found for kidney weight (0.58 +/- 0.01 g vs. 0.51 +/- 0.01 g in controls, P < 0.001). In contrast, serum glucose (9.73 +/- 0.29 mmol/l compared to 11.80 +/- 0.42 mmol/l in controls, P < 0.0005) was decreased. However, there was no significant difference in nose-tail length of tumour-bearing compared to control mice. These results demonstrate that besides the highly increased IGF-II-mRNA, the synthesis of the peptide IGF-II and its release into circulation are also elevated in Wilms tumour transplanted into nude mice.(ABSTRACT TRUNCATED AT 250 WORDS)
Previous results showed maximally enhanced basal glucose transport in adipocytes of hypophysectomized rats and restoration to normal after human growth hormone (hGH) administration. The data suggested a hGH-dependent "limiting factor" for glucose transport in the adipocyte membrane, which is acutely inhibited by insulin resulting in enhanced glucose transport. In this study the effect of hGH was investigated with respect to dose and time dependence. hGH was administered by continuous infusion from subcutaneously implanted Alzet minipumps. A significant decrease of basal glucose transport was obtained at the lowest hGH dose of 50 mU/day for 6 days. This effect of hGH was strictly correlated to the effects on growth (tibial epiphyseal width, DNA synthesis, body weight, serum level of insulin-like growth factor). The effect of hGH on basal glucose transport was already observed after 12 h of infusion, and it increased to a maximum after 3 days. The data support the concept that GH regulates the glucose transport system in adipose tissue in vivo.
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