Monoiodotyrosine

Abstract: Mouse peritoneal macrophages take up I*-HSA from their medium during in vitro cultivation. Conditions which promote I*-HSA uptake are the same as those which stimulate formation of pinocytic vesicles. Autoradiography of cells pulsed with 125I-HSA showed that intracellular isotope is localized in perinuclear granules, or secondary lysosomes. Following a pulse of 125I-HSA, intracellular radioactivity decreases and the amount of TCA-soluble isotope in the medium increases correspondingly. About 50% of the intracellular isotope is lost in 5 hr. The release of isotope from pulsed cells is not inhibited by parafluorophenylalanine, 2,4-dinitrophenol or by a reduction of the serum concentration of the medium. However, the processing of ingested 125I-HSA is reversibly inhibited by reduced temperature. The TCA-soluble radioactive material excreted by pulsed macrophages was identified as monoiodotyrosine.

Abstract: The mechanism responsible for the hyperdynamic circulatory state in hyperthyroidism has not been defined. Although certain cardiac manifestations resemble those caused by excessive adrenergic stimulation, recent evidence suggests that thyroid hormone exerts an effect on the heart that is independent of the adrenergic system. Since the inotropic and chronotropic effects of norepinephrine appear to be mediated by activation of adenyl cyclase, the possibility that thyroxine and triiodothyronine are also capable of activating adenyl cyclase was examined in the particulate fraction of cat heart homogenates. L-thyroxine and L-triiodothyronine increased the conversion of adenosine triphosphate-32P (ATP-32P) to cyclic 3′,5′-adenosine monophosphate-32P (3′,5′-AMP-32P) by 60 and 45% respectively (P < 0.01). A variety of compounds structurally related to the thyroid hormones, but devoid of thyromimetic activity did not activate adenyl cyclase: these included 3,5-diiodo-L-thyronine, L-thyronine, 3,5-diiodotyrosine, monoiodotyrosine, and tyrosine. D-thyroxine activated adenyl cyclase and half maximal activity was identical to that of the L-isomer. Although the beta adrenergic blocking agent propranolol abolished norepinephrine-induced activation of adenyl cyclase, it failed to alter activation caused by thyroxine. When maximal concentrations of L-thyroxine (5 × 10-6 moles/liter) and norepinephrine (5 × 10-5 moles/liter) were incubated together, an additive effect on cyclic 3′,5′-AMP production resulted. This investigation demonstrates: (a) thyroid hormone is capable of activating myocardial adenyl cyclase in vitro and (b) this effect is not mediated by the beta adrenergic receptor. Moreover, the additive effects of norepinephrine and thyroxine suggest that at least two separate adenyl cyclase systems are present in the heart, one responsive to norepinephrine, the other to thyroid hormone. These findings are compatible with the hypothesis that the cardiac manifestations of the hyperthyroid state may, in part, be caused by the direct activation of myocardial adenyl cyclase by thyroid hormone.

Abstract: Triiodothyronine (T(3)) and thyroxine (T(4)) were measured by immunoassay in the serum and thyroid hydrolysates of control (group A), mildly iodine-deficient (group B), and severely iodine-deficient rats (group C). These results were correlated with changes in thyroidal weight, (131)I uptake and (127)I content as well as with the distribution of (131)I in Pronase digests of the thyroid. There was a progressive increase in thyroid weight and (131)I uptake at 24 h with decrease in iodine intake. The (127)I content of the thyroids of the group B animals was 44% and that of the group C animals 2% of that in group A. The mean labeled monoiodotyrosine/diiodotyrosine (MIT/DIT) and T(3)/T(4) ratios in group A were 0.42+/-0.07 (SD) and 0.12+/-0.01, 0.59+/-0.06 and 0.11+/-0.03 in group B, and 2.0+/-0.3 and 1.8+/-0.9 in the group thyroid digests.Mean serum T(4) concentration in the control rats was 4.2+/-0.6 (SD) mug T(4)/100 ml, 4.5+/-0.3 mug/100 ml in group B animals, and undectectable (<0.5 mu(4)/100 ml) in group C animals. There was no effect of iodine deficiency on serum T(3) concentrations, which were 44+/-9 (Mean+/-SD) ng/100 ml in A animals, 48+/-6 ng/100 ml n B animals, and 43+/-6 ng/100 ml in the C group. Thyroidal digest T(3) and T(4) concentrations were 39 and 400 ng/mg in group A animals and were reduced to 5 and 1% of this, respectively, in group C. The molar ratio of T(3)/T(4) in the thyroid digests of the groups A and B animals was identical to the ratio of labeled T(3)/T(4) and was slightly less (1.0+/-0.9) than the labeled T(3)/T(4) ratio in the group C animals. The mean ratio of labeled T(4) to labeled T(3) in the serum of the severely iodine-deficient animals 24 h after isotope injection was 11+/-1 (SEM). With previously published values, it was possible to correlate the ratio of labeled T(4)/T(3) in the thyroid digest with the labeled T(4)/T(3) ratio in the serum of each iodine-deficient animal. This analysis suggested that the labeled thyroid hormones in the severely iodine-deficient rat were secreted in the ratio in which they are present in the gland. Kinetic analysis of total iodothyronine turnover indicated that two-thirds of the T(3) utilized per day by the iodine-sufficient rat arises from T(4). If the T(4)-T(3) conversion ratio remains the same in iodine deficiency, then the analysis suggests that about 90% of the T(3) arises directly from the thyroid. Therefore, it would appear that absolute T(3) secretion by the thyroid increases severalfold during iodine deficiency. The fact that serum T(3) remains constant and T(4) decreases to extremely low levels, combined with previous observations that iodine-deficient animals appear to be euthyroid, is compatible with the hypothesis that T(4) in the normal rat serves primarily as a precursor of T(3).

Abstract: The overwhelming majority of atrial natriuretic factor (ANF) receptors in kidney and vascular tissues do not mediate any of the known functional effects of the hormone. To test whether these receptors (C-ANF receptors) function as clearance receptors for circulating ANF-(1-28), we determined the effects of C-ANF-(4-23) [des[Gln18Ser19Gly20Leu21Gly22]rANF-(3-23)-NH2], a specific ligand of C-ANF receptors, on the pharmacokinetics and hydrolysis of 125I-labeled ANF-(1-28) in anesthetized rats. Radioactivity in plasma was characterized by trichloroacetic acid solubility and high-pressure liquid chromatography. C-ANF-(4-23) (1 and 10 micrograms.min-1.kg body wt-1) led to marked dose-dependent increases in initial plasma concentration of administered 125I-ANF-(1-28) and decreases in its volume of distribution at steady state (Vss), metabolic clearance rate (MCR), and appearance of hydrolytic products ([125I]monoiodotyrosine and free 125I) in plasma (Pm). At the highest dose, C-ANF-(4-23) decreased Vss from 97 +/- 12 to 36 +/- 2 ml/100 g body wt, MCR from 50 +/- 4 to 12 +/- 1 ml.min-1.100 g body wt-1, and Pm from 54 +/- 8 to 11 +/- 2% of initial plasma 125I-ANF-(1-28). The data demonstrate that C-ANF receptors are mainly responsible for the very large volume of distribution and fast MCR of ANF in the rat. In this manner, C-ANF receptors are likely to play an important role in the homeostasis of circulating ANF.