Modulation of insulin induced ornithine decarboxylase by putrescine and methylputrescines in H-35 hepatoma cells.

The effect of several methylputrescines on the activity of insulin-induced ornithine decarboxylase (ODC) was examined in H-35 hepatoma cells. The induction involved both protein and m-RNA synthesis. Actinomycin D inhibited ODC activity when given up to 1 h after insulin treatment. When added to the medium 2 h or 3 h after the insulin, the activity was increased 100% and 80% respectively. Insulin-induced ODC from H-35 cells had a biphasic half-life, a shorter one of 46 min and a longer one of 90 min. 1-Methylputrescine and 2-methylputrescine were found to be competitive inhibitors of the ODC from H-35 cells with Ki values of 2.8 and 0.1 mM respectively. Putrescine itself was found to have a Ki = 2.4 mM. N-Methylputrescine was a very poor inhibitor of the cell free ODC while 1,4-dimethylputrescine did not show any inhibitory effect. When cellular ODC activity was measured, the four methylputrescines assayed as well as putrescine entirely abolished its activity in the H-35 cells when given at a 1 mM concentration together with insulin. 1-Methylputrescine and 1,4-dimethylputrescine abolished 60% of the activity at a 0.1 microM concentration. All the methylputrescines given at 0.1 mM concentrations decreased the putrescine content of the stimulated cells to the levels found in quiescent cells, but only 1-methyl and 2-methylputrescines decreased spermidine and spermine content. 1,4-Dimethyl and 1-methylputrescines showed a strong inhibition of ODC synthesis, while the other diamines were less inhibitory. At concentrations that abolished ODC activity, 1,4-dimethylputrescine decreased 70% of the total immunoreactive ODC bands, while 1-methyl and 2-methylputrescine decreased them by 50%, and N-methylputrescine and putrescine decreased them by 20%. The lack of decrease in immuno-reactive ODC with the latter two compounds was mainly due to the appearance of immunoreactive degradation products of ODC of low molecular weight. Putrescine and N-methylputrescine affected protein synthesis to a small extent in stimulated cells, while 1-methylputrescine decreased it to the level of non-stimulated cells. Insulin (1 microM concentration) stimulated DNA synthesis in the cells, and this stimulation was doubled in the presence of 2-methylputrescine or putrescine. It can be concluded that, among the methylputrescines assayed, 2-methylputrescine was the best inhibitor of cell-free ODC activity, while 1,4-dimethylputrescine and 1-methylputrescine were the best inhibitors of cellular ODC activity.

Membrane methylation in isolated rat testis interstitial cells unmasks functional luteinizing hormone receptors.

Treatment of intact isolated rat testis interstitial cells with S-adenosylmethionine as methyl donor, increases substantially the number of LH human CG receptors (100-200%) without modifying the equilibrium dissociation constant. The increase in binding capacity was associated with an augmentation in the sensitivity of the rat testis interstitial cells to produce testosterone in response to LH, suggesting a functional role of the unmasked receptors. The amount of S-adenosylmethionine necessary to obtain an increase in LH binding capacity and preserve cell viability was 25-50 micrograms/ml per 1.6 X 10(7) cells. 10 mM MgCl2 in addition to the Mg2+ present in the medium was necessary to maintain cell viability. 3H-labelled methyl groups were incorporated mainly into the lipid fraction (208 fmol/10(6) cells) when 3H-S-adenosylmethionine was incubated with the cells for 2 h at 30 degrees C. Our results are consistent with the conclusion that early action of LH may involve an activation of methyltransferase activity, phospholipid methylation, an increase in LH binding capacity and an increase in receptor function.

Characterization of the insulin-binding sites in turtle thyroid microsomes.

The characteristics of the specific binding of labelled insulin to turtle thyroid microsomes were investigated. Binding experiments were performed in Krebs-Ringer bicarbonate buffer (pH 7.4) at 25 or 4 degrees C for different periods of time. Dissociation of the labelled insulin from the binding sites was also evaluated. It was found that the binding is dependent on time, temperature and microsomal protein concentration, with an optimum pH of 8.0. Unlabelled insulin and pro-insulin competed with the labelled insulin, binding in direct proportion to their biological activities, while glucagon and growth hormones did not compete for the binding sites. Scatchard plot analysis established the presence of binding sites of high and low affinities, and the rate of dissociation of bound insulin was considerably increased by the addition of unlabelled insulin. Both results are compatible with a negative co-operativity site-site interaction model. Trypsin abolished the insulin binding. These findings indicate that the microsomes from the turtle thyroid gland contain specific binding sites for insulin. However, pre-incubation of microsomes with phospholipase C or S-adenosyl-L-methionine (SAM), or incubation in the presence of 2 mol NaCl/l did not increase the specific insulin binding. Therefore, the binding properties are similar to those observed in mammalian insulin-responsive tissues except for the absence of the effects of 2 mol NaCl/l, phospholipase C or SAM, which suggests the absence of masked insulin-binding sites.

Unmasking of insulin receptors in rat submaxillary gland microsomes: effect of high ionic strength, phospholipase C and S-adenosyl-L-methionine.

The specific binding of [125I]insulin to submaxillary gland microsomes was significantly enhanced by increasing the ionic strength of the incubation medium. This effect was neither related to changes in receptor or hormone degradation nor in the polymerization of the tracer. When equilibrium binding data from competition curves of unlabelled insulin versus [125I]insulin were analyzed, a marked increase in total binding capacity in high ionic strength was observed (from 890 to 2440 fmol/mg protein), with no change in binding affinity. Phospholipase C digestion was also able to increase specific [125I]insulin binding to microsomes. These results suggest the presence of masked receptors in submaxillary gland microsomes. Methylation of rat submaxillary gland microsomes by using S-adenosyl-L-methionine as the methyl donor significantly increased [125I]insulin binding. Scatchard analysis of the equilibrium binding data showed that addition of S-adenosyl-L-methionine (0.46 mM) to microsomes resulted in an enhancement of the total binding capacity (from 990 to 1520 fmol/mg protein) with no change in the affinity constants, which suggests the exposure of masked insulin receptors under such conditions. Both the methyl group incorporation into membrane phospholipids and the effect on insulin binding were dependent on the S-adenosyl-L-methionine concentration used and were partially suppressed in the presence of S-adenosyl-L-homocysteine, a specific competitive inhibitor of the methyltransferases activity. When microsomes were treated with S-adenosyl-L-[methyl-3H]methionine, the 3H-labelled methyl groups incorporated were found mainly in the lipid fraction associated to phosphatidylcholine, suggesting in this case that the unmasking of insulin receptors could be a consequence of alterations produced in membrane composition. The effects of phospholipase C, S-adenosyl-L-methionine and high ionic strength on insulin binding were not additive, suggesting that these procedures unmask receptors from the same pool.

Characteristics of insulin receptors in a clonal line of rat pituitary tumor cells in culture.

The presence of insulin binding sites in a clonal line of cells from rat pituitary tumor (GH1 cells) is described. The binding of insulin was a reversible and specific process. Binding of 125I-insulin to GH1 cells was inhibited by unlabeled insulin and to a minor extent, by proinsulin and desalanine insulin in direct proportion to their biological activities. Trypsin abolished the insulin binding to the cells. Twelve hours incubation of cells with insulin (5 microM) reduced in a 45% of the number of binding sites for the hormone. 125I-insulin bound to GH1 cells dissociated with a t 1/2 of 8 min. At 24 C labeled insulin was degraded by GH1 cells. No degradation was detected at 6 C. Unlabeled insulin inhibited most of the degradation of 125I-insulin, suggesting that degradation resulted from a saturable process. At steady-state, radioactive degradation products as well as 125I-insulin were recovered from GH1 cells.