Intrathyroidal iodine metabolism in the rat. The influence of diet and the administration of thyroid-stimulating hormone

1. Ratios of mono[¹³¹I]iodotyrosine and di[¹³¹I]iodotyrosine (R values) and the incorporation of ¹³¹I into iodothyronines have been estimated in rat thyroid glands from 30min. to 38hr. after the administration of [¹³¹I]iodide. 2. In rats receiving a powdered low-iodine diet the R values were close to unity and did not change with time after the administration of [¹³¹I]iodide. In rats receiving a commercial pellet diet the R values fell from a mean of 0·8 at 30min. after [¹³¹I]iodide administration to 0·49 at 38hr. 3. Administration of 0·5–2·0i.u. of thyroid-stimulating hormone before giving the injection of [¹³¹I]iodide caused a small diminution in the R value when the time between injecting [¹³¹I]iodide and killing the animal was 16hr. or more. 4. Iodothyronines represented a greater percentage of the total thyroid-gland radioactivity in the iodine-deficient animals than in animals fed on the pellet diet. Thyroid-stimulating hormone had little effect, if any, on the iodothyronine contents.     

Disturbance of thyroidal iodine metabolism in BB/W rat.

To investigate the thyroid function in Bio-Breeding Worcester (BB/W) rats, we have examined the iodine metabolism, serum TSH and thyroid hormone levels in 8- and 16-week-old BB/W and normal Wistar (W) rats. At 8 weeks of age, serum TSH levels were significantly higher in BB/W rats than in W rats, although there was no difference in the serum levels of free T3 and free T4. Furthermore, the thyroidal radioactive iodine incorporation at 48 h was significantly lower in BB/W rats, suggesting that they might have some defects in iodine organification. At 16 weeks of age, serum TSH levels were also significantly higher in BB/W rats than in W rats. Furthermore, serum TSH levels in 16-week-old BB/W rats were significantly higher than in 8-week-old BB/W rats. The thyroid weight was significantly greater in BB/W rats, probably due to the increased serum TSH. The thyroidal radioactive iodine uptake at 48 h and the iodine content in the thyroid homogenates were significantly lower in BB/W rats. These results suggest that BB/W rats have some defect in iodine metabolism resulting in impaired thyroid hormone synthesis.     

The intracellular metabolism of iodine in carcinogenesis

Research from this laboratory and others have concluded that significant glandular atypia, and often neoplasia, occurs in the breast tissues of rodents and humans under conditions of iodine deprivation. These cellular changes caused by iodine deficiency are intensified, by aging, steroid hormones, and pituitary hormones. There has been controversy concerning the effect of iodine deficiency on stimulation and maintenance of cancer of the breast in rodents when the cancer is induced chemically or by transplantation. However, neither within this induced neoplastic framework nor with the dysplastic changes seen by deficiency alone have laboratory studies of thepathway of intracellular iodine been previously possible. The new research data addresses the question of whether organification occurs and whether iodine significantly affects the intracellular structures. An hypothesis will be presented that places the inorganic element, iodine, into association with receptor protein complexes that may be responsible for intracellular sex hormone activity. The relationship of this mechanism to carcinogenesis in breast tissue will be considered.     

The metabolism of cyclohexanecarboxylate in the rat.

In the rat, cyclohexanecarboxylate was metabolized and excreted (mostly in the urine) as hippurate, hexahydrohippurate, 3,4,5,6-tetrahydrohippurate and benzoyl and cyclohexylcarbonyl beta-glucuronides. The pattern of metabolism is dose-dependent. With decreasing dose a progressive increase in the conversion into hippurate occurred. This was largely at the expense of glucuronide formation, although the proportions of hexahydro- and tetrahydro-hippurate were also decreased. The observed formation of hexahydrohippurate and 3,4,5,5-tetrahydrohippurate substantiates the proposed mechanism of aromatization of cyclohexanecarboxylate. It appears that these compounds arise via glycine conjugation of active intermediates in the aromatization process. Hexahydrohippurate and 3,4,5,6-tetrahydrohippurate may occur in the urine of rats as new mitabolities of shikimate, dependent for their formation on microbial metabolism.     

The metabolism of shikimate in the rat.

In the rat, shikimate was metabolized and excreted as hippurate, hexahydrohippurate, 3,4,5,6-tetrahydrohippurate, t-3,t-4-dihydroxycyclohexane-r-1-carboxylate and c-3,t-4-dihydroxycyclophexane-r-1-carboxylate, conjugates of catechol and CO2. The metabolism was entirely dependent on various initial microbial transformations in the gut, metabolite formation being suppressed in animals pretreated with antibiotics. Shikimate was not metabolized by mammalian tissues, and products of microbial metabolism were excreted either unchanged or after further biotransformation in the animal tissues.     

The perinatal thyroid in iodine deficient regions: risks of radioiodines--hazards of stable iodine overload. A study in the newborn rat.

Administration of large quantities of stable iodine is an effective means of reducing the radiation burden on the thyroid in the event of a nuclear power-plant accident. Such administration may involve countries with low baseline dietary iodine intake. It is questioned whether stable iodine overload is safe, and in particular, what are its effects in newborn infants? Iodine-deficient newborn rats were submitted to a single acute administration of stable iodine (100 microg) on the second day of life. The effects on thyroid structure were studied, after 24 hr and after 7 days, using light microscopy. Compared to controls, the thyroids of animals submitted to stable iodine overload showed, 7 days after treatment, signs of acute toxicity including marked desquamation of epithelial cells and rupture of a large number of thyroid follicles. Our findings in iodine deficient newborn rats suggest that stable iodine overload may have side effects during perinatal life. This prophylactic measure should, therefore, be accompanied by follow-up of thyroid function. Thyroid hormones are critical for brain development, during the first period of life.