Significance of serum thyrotropin and plasma dopamine concentration in the regulation of thyroid function in elderly subjects

In our previous study, we observed a tendency towards an age-related increase in the serum thyrotropin (TSH) concentration. Regulatory mechanisms of TSH secretion in elderly subjects were studied. In 43 elderly subjects, serum TSH did not correlate significantly with serum T4, T3 free T4 or rT3. Further, those with increased TSH (greater than 5 mU/l, 9 subjects) did not overlap with those with low T3 (less than 0.92 nmol/1, 8 subjects). Increases in serum TSH were not associated with the presence of circulating anti-thyroid autoantibodies. A TRH test using a 500 micrograms single bolus injection was performed in 15 subjects. TSH response (basal: 1.92 +/- 1.42 (s.d.) mU/1, peak: 11.25 +/- 5.33 mU/1, sigma: 26.74 +/- 12.89 mU/1, respectively) did not differ significantly from that of younger subjects. T3 response after TRH varied greatly and a close correlation was observed between basal T3 and peak T3 (r = 0.86), and also between peak T3 and delta T3 (r = 0.81). A significant correlation was observed between sigma TSH and basal T3 (r = 0.60). Neither plasma cortisol, epinephrine nor norepinephrine concentrations showed any significant correlation with basal and TRH-stimulated TSH or T3 concentrations. However, the plasma dopamine concentration correlated significantly with sigma TSH (r = 0.60) and basal T3 (r = 0.52), respectively. In conclusion, the increase in serum TSH observed in elderly subjects was felt to represent a physiological adaptation to maintain serum T3. Low T3 subjects appear to have a disturbance in this mechanism, with decreased TSH and T3 response to TRH stimulation.(ABSTRACT TRUNCATED AT 250 WORDS)     

rT3 production in normal man, assessed from variations in serum rT3 during short-term rT3 infusion.

The metabolic clearance rate (MCR) of 3,3'5'-triiodothyronine (reverse T3, rT3) was estimated in normal human subjects by a modified noncompartmental method using the integrated increase in serum rT3 following intravenous infusion of 0.10 nmol/min rT3 for 4 hr. The MCR-rT3 was calculated to be 102.8 +/- 17.01/day and the daily rT3 disposal to be 33.0 +/- 9.5 nmol (mean +/- SD, n = 6). The MCR-rT3 compares well to that of previous studies employing tracer kinetic methods. The disposal rate of rT3 estimated in the present study is considerably lower than found in some previous studies. The discrepancy is due to differences in the measured levels of serum rT3 in normal subjects.     

Lowering of T3 and rise in reverse T3 induced by hyperglucagonemia: altered thyroid hormone metabolism, not altered release of thyroid hormones

Recently we reported that hyperglucagonemia induced by glucagon infusion causes a decline in serum T3 and a rise in reverse T3 in euthyroid healthy volunteers. These changes in T3 and rT3 levels were attributed to altered T4 metabolism in peripheral tissues. However, the contribution of altered release of thyroid hormones by the thyroid gland could not be excluded. Since the release of thyroid hormones is inhibited in primary hypothyroidism and is almost totally suppressed following L-thyroxine replacement therapy, we studied thyroid hormone levels for up to 6 hours after intravenous administration of glucagon in subjects with primary hypothyroidism who were rendered euthyroid by appropriate L-thyroxine replacement therapy for several years. A control study was conducted using normal saline infusion. Plasma glucose rose promptly following glucagon administration demonstrating its physiologic effect. Serum T4, Free T4, and T3 resin uptake were not altered during both studies. Glucagon infusion induced a significant decline in serum T3 (P less than 0.05) and a marked rise in rT3 (P less than 0.05) whereas saline administration caused no alterations in T3 or rT3 levels. Thus the changes in T3 and rT3 were significantly different during glucagon study when compared to saline infusion. (P less than 0.01 for both comparisons). Since, the release of thyroid hormones is suppressed by exogenous LT4 administration in these subjects; we conclude that changes in serum T3 and rT3 observed following glucagon administration reflect altered thyroid hormone metabolism in peripheral tissues and not altered release by the thyroid gland.     

Decline of T3 and elevation in reverse T3 induced by hyperglucagonemia: changes in thyroid hormone metabolism, not altered release of thyroid hormones

Recently we reported that hyperglucagonemia induced by glucagon infusion causes a decline in serum Triiodothyronine (T3) and a rise in reverse T3 (rT3) in euthyroid healthy volunteers. These changes in T3 and rT3 levels were attributed to altered T4 metabolism in peripheral tissues. However, the contribution of altered release of thyroid hormones by the thyroid gland could not be excluded. Since the release of thyroid hormones is suppressed by exogenous administration of L-thyroxine (L-T4) in appropriate dosage, we studied thyroid hormone levels for up to 6 hours after intravenous administration of glucagon in euthyroid healthy subjects after administration of L-T4 for 12 weeks. A control study was conducted using normal saline infusion. Plasma glucose rose promptly following glucagon administration demonstrating its physiologic effect. Serum T4, Free T4 and T3 resin uptake were not altered during both studies. Glucagon infusion induced a significant decline in serum T3 (P less than 0.01) and a marked rise in rT3 (P less than 0.01) whereas saline administration caused no alterations in T3 or rT3 levels. Thus the changes in T3 and rT3 were significantly different during glucagon study when compared to saline infusion. (P less than 0.01 for both comparisons). Therefore, this study demonstrates that changes in serum T3 and rT3 caused by hyperglucagonemia may be secondary to altered thyroid hormone metabolism in peripheral tissues and not due to altered release by the thyroid gland, since the release of thyroid hormones is suppressed by exogenous L-T4 administration.     

Effects of the infusion of glucagon on the blood levels of thyroid hormones

We have attempted to determine if mild hyperglucagonemia induced by exogenous glucagon infusion induces changes of serum thyroid hormone levels. Eleven healthy subjects, overnight fasting, received glucagon infusion (2 mg/90 min i.v.), whereas 5 healthy subjects (control group) received normal saline infusion. In the subjects infused with exogenous glucagon plasma glucagon concentrations increased from 130 +/- 24 pg/ml to 550 +/- 68 pg/ml at the end of infusion. At the same time no significant changes in serum T3, rT3 and T4 levels were found. A significant increase in serum rT3 levels was found 270 min after glucagon infusion withdrawal, whereas serum T4 levels remained unaltered during the whole period. Normal saline infusion failed to induce any variation in control group, however a late (at 6th hour) mild increase of serum rT3 in these subjects resulted comparable to the same increase of glucagon infused subjects. The results from this study suggest that mild increase in plasma glucagonemia, as found in patients with severe illness, does not induce a short-time significant lowering of serum T3 and a simultaneous rise of serum rT3 in normal subjects.     

The pituitary-thyroid axis in acromegaly

The pituitary-thyroid axis of 12 acromegalic patients was evaluated by measurement of the serum concentrations (total and free) of thyroxine (T4), triiodothyronine (T3) and reverse T3 (rT3) and thyrotropin (TSH), growth hormone (GH) and prolactin (PRL) before and after iv stimulation with thyrotropin releasing hormone (TRH). Using an ultrasensitive method of TSH measurement (IRMA) basal serum TSH levels of the patients (0.76, 0.07-1.90 mIU/l) were found slightly, but significantly (P less than 0.01), lower than in 40 healthy controls (1.40, 0.41-2.50 mIU/l). The total T4 levels (TT4) were also reduced (84, 69-106 nmol/l vs 100, 72-156 nmol/l, P less than 0.01) and significantly correlated (P less than 0.02, R = 0.69) to the TSH response to TRH, suggesting a slight central hypothyroidism. The acromegalics had, however, normal serum levels of TT3 (1.79, 1.23-2.52 nmol/l vs 1.74, 0.78-2.84 nmol/l, P greater than 0.10), but significantly decreased levels of TrT3 (0.173, 0.077-0.430 nmol/l vs 0.368, 0.154-0.584 nmol/l, P less than 0.01) compared to the controls. The serum concentration of the free iodothyronines (FT4, FT3, FrT3) showed similar differences between acromegalics and normal controls. All the acromegalics showed a rise of serum TSH, GH and PRL after TRH. Positive correlation (P less than 0.05, R = 0.59) was found between the TSH and GH responses, but not between these two parameters and the PRL response to TRH. These findings may be explained by the existence of a central suppression of the TSH and GH secretion in acromegalic subjects, possibly exerted by somatostatin. Euthyroidism might be maintained by an increased extrathyroidal conversion of T4 to T3.     

Iodothyronine content in the pig thyroid gland

An analysis has been carried out on the contents and reciprocal proportions of three principal iodothyronines (T4, T3 and rT3) in the thyroids of fed and fasted piglets of 8-10 wk and in adult pigs. The mean T4 concentration averaged 62.0 +/- nmol/100 mg wet tissue (in adults: 18.5 +/- 4.3 nmol/100 mg tissue); T3, 9.5 +/- 0.9 nmol/100 mg tissue (in adults: 1.58 +/- 0.2 nmol/100 mg tissue); rT3, 3.0 +/- 0.3 nmol/100 mg tissue. The reciprocal ratios of the hormones in the piglets' thyroids were: for T3:T4, 0.150 (in adults, 0.114) and for rT3:T4, 0.050 (in adults, 0.023). Mean T4:T3:rT3 ratio in piglets and adult pigs was 20.5:3.1:1 and 66.1:5.6:1, respectively. The results from all examined iodothyronines, show the higher absolute concentration in piglets' than in adult pigs' thyroid tissue, while the reciprocal proportions of the hormones reveal smaller T4 thyroid contents (comparing with T3 and rT3) in piglets than in adults. No changes of absolute thyroidal contents or reciprocal ratios of the iodothyronines were observed in fed and fasted piglets. In a comparison, the pig thyroid contains more triiodothyronine and a higher ratio T3:T4 than that in some other species.     

Can the type of variant albumin in familial dysalbuminemic hyperthyroxinemia be determined by measuring iodothyronines in serum?

A recent report documented the existence of three putative types of variant albumin in dysalbuminemic hyperthyroxinemia (DH) and suggested that measurement of the total concentration of three iodothyronines (T4, T3 and rT3) in serum of affected subjects could aid in their differentiation. In the present report, we describe three affected subjects from a single family which DH exhibited, in addition to increased serum total T4 levels, variable changes in the concentrations of total T3 and rT3. The concentrations of the following iodothyronines were above the normal limit: T4, T3 and rT3 in the propositus, T4 and T3 but not rT3 in her sister, and T4 but not T3 and rT3 in her mother. These differences cannot be caused by structurally different types of variant albumins, because the three subjects are members of the same family. They rather correlated with the relative abundance of the variant albumin in serum of the affected family members. Although previously reported subjects with DH always had serum T4 levels above the normal limit due to the predominantly higher affinity of the variant albumin for T4, significant increases in the concentration of serum T3 and rT3, reaching at times values above the upper normal range, have also been observed. Since a number of factors, including the relative abundance of the variant albumin, influence the concentration of iodothyronines in serum, their measurement alone cannot be used to determine the inherited type of DH.     

Effect of acute intravenous administration of thyroliberin on circulating reverse-T3

Some of the Authors previously demonstrated a significant precocious serum T3 increase after 200 micrograms TRH acute intravenous administration (TRH test). Reverse-T3 (rT3) is now known to interfere with T4 conversion to T3. We therefore compared spontaneously occurring to TRH test-induced changes in T3 and rT3 serum levels within a group of four healthy women in fertile age. Maximum rT3 increase during TRH test did not differ significantly from the maximum spontaneous variation at the same time of the day. Maximum T3 increase, on the contrary, was significantly higher than observed maximum spontaneous variation (0,81 ng/ml versus 0,39 ng/ml increase, p less than 0,01). Possible implications are discussed in the text.     

Comparison between spontaneous changes in circulating triiodothyronine (T3 and reverse-T3) and those induced by acute intravenous administration of thyroliberin

Some of the Authors had previously observed a slight-non significant decrease in T3 serum levels 10 minutes after TRH intravenous administration. On the other hand, it is now well known that reverse T3 (rT3) inhibits T4 conversion to T3. We therefore investigated the changes in T3 and rT3 serum levels within the first ten minutes of a 200 micrograms TRH test in a group of 10 healthy women in fertile age. No significant change in T3 was demonstrated. On the other hand, rT3 showed a significant-yet slight-decrease 6 minutes after TRH injection (from 0,27 to 0,21 ng/ml, p less than 0,05). Some feasible explanations for this phenomenon are given in the text.     

A study of hepatic metabolism of thyroxine in BB/W rats treated with L-thyroxine

The effect of thyroxine (T4) on T4 conversion to triiodothyronine (T3) and reverse T3 (rT3) was studied in BB/W rats. A colony of 38 BB/W rats was obtained and half were treated with thyroxine (T4), 1 mg per liter of drinking water. At 106 days of age the following groups were identified: nondiabetic, no T4 treatment, 8 rats; nondiabetic, T4 treated, 8 rats; diabetic, no T4 treatment, 10 rats; diabetic, T4 treated, 7 rats. All animals with diabetes were treated with insulin. T4 conversion to T3 and rT3 was assessed in liver homogenates in 0.1 M Tris-HCl buffer, pH 7.4, with or without 5 mM dithiothreitol (DDT). Serum T4 and rT3 were significantly elevated in both T4-treated groups (P less than 0.001), while serum T3 was not affected in either. Basal T4 deiodination to T3 by the liver homogenate did not change on treatment with T4; the addition of DTT increased T3 production in the homogenate from T4 treated nondiabetic animals (P less than 0.05). In both nondiabetic and insulin-treated diabetic rats there was no effect of T4 on the rate of rT3 production. Since, in the rat, 30-40% of circulating T3 is a direct contribution of thyroid gland secretion, and that would be absent in our T4-suppressed animals, the normal serum T3 may reflect increased absolute peripheral T3 production from the greater concentration of circulating T4.     

Simultaneous observations of iodothyronine content in the thyroid gland, serum and thyroxine 5'- and 5-monodeiodinase activity in liver, during the neonatal period of the pig

Serum T4 and rT3 were high at about 4-12 h after birth, then they decreased to a nadir on day 3 (rT3) and day 7 (T4). Serum T3 concentration fell immediately after birth but then increased to a relatively stable level during the next 2-6 weeks, then fell after weaning. Reciprocal concentration profiles of T4, T3 and rT3 in the thyroid were found. The thyroidal iodothyronine content increased significantly after weaning. In the liver, 5'-monodeiodinating activity, low after birth, rose until day 3 and then decreased concomitantly with T3 in serum. The 5-monodeiodinating activity, high at birth, fell to a nadir at about 3 weeks. No changes in 5- and 5'-deiodinase activity after 3 weeks were observed. Opposite to the variations in absolute content, the iodothyronine relative proportion in thyroid tissue was practically unchanged until weaning time (6 weeks), when they rose. Serum T3/T4 and rT3/T4 ratios increased with age until weaning. The post-weaned pigs had T3/T4 and rT3/T4 ratios about two times smaller than 6-weeks-old pigs. Serum rT3/T3, high after birth, decreased with age. Summarizing, the results indicate that neither changes in the thyroid iodothyronine content nor in the liver T4-monodeiodinating activity can solely account for variations in serum TH during the early neonatal period in the pig. It is suggested that the rapid variations in serum TH levels can reflect changes in the thyroidal secretory activity in preferential T3 secretion and/or blood disappearance rates.     

Low T3 syndrome in cancer patients in relation to weight loss, intravenous hyperalimentation therapy and age

In order to investigate the relation of weight loss and intravenous hyperalimentation therapy to low T3 syndrome, serum T3, T4. rT3 and TBG were determined by radioimmunoassay in 105 cancer patients. The cancer patients were classified into 3 groups, Group I, II and III depending on the grade of weight loss, ranging up to a 5% change in weight loss from a healthy condition, from 5 to 9%, and more than 10%, respectively. Cancer patients under age 59 showed no significant difference in serum T3, T4, rT3 and TBG among these 3 groups. However serum T3 and T3/T4 in cancer patients at age 60 and over were significantly reduced in group III, compared to groups I and II. Serum rT3 values were significantly elevated in group III of elderly cancer patients. The incidence of low T3 syndrome in group III of elderly cancer patients was also significantly higher than in groups I and II. In three out of 5 cancer patients with low T3 syndrome, serum T3 values increased after the intravenous hyperalimentation therapy, whereas no significant change in serum T3 values was observed in two patients who died within one day after the final examination. It is concluded that weight loss produced different effects on peripheral conversion of T4 to T3 between cancer patients under age 59 and over age 60 and glucose plays an important role in the pathogenesis of low T3 syndrome except cases with very poor prognosis.     

Apparent increase in type I 5'-deiodinase activity induced by antiepileptic medication in mentally retarded subjects

BACKGROUND/OBJECTIVES: Thyroid function measurements in 3 mentally retarded patients treated with antiepileptic drugs (phenytoin or carbamazepine) showed normal thyroid-stimulating hormone (TSH) responses in spite of markedly low levels of total thyroxine (T(4)), triiodothyronine (T(3)), and free thyroxine (FT(4)) concentrations; free triiodothyronine (FT(3)), as well as mean thyroxine-binding globulin (TBG) concentrations were normal. The objective of the present investigations was to determine if antiepileptic medication in these patients contributed to the disparate TSH and thyroid hormone (TH) levels. METHODS: Thyroid tests and other laboratory parameters were measured by conventional techniques. RESULTS: Circulating TH changes noted in retarded patients were similar to those observed in control subjects receiving carbamazepine alone. Reverse T(3) (rT(3)) levels in all patients were either undetectable or below the normal range. CONCLUSIONS: As type I 5'-deiodinase has a higher affinity for rT(3) than T(4), an increased activity of this enzyme would enhance rT(3) deiodination and reduce serum rT(3) concentration whereas enhanced T(4) deiodination would aid in normalizing intracellular FT(3) concentration. The finding of normal serum FT(3) concentration was consistent with normal TSH response and clinical euthyroidism in both retarded and control subjects. While phenytoin-induced increase in type I 5'-deiodinase has been previously noted, the present studies demonstrate a similar effect of carbamazepine on 5'-deiodinase.     

Thyroid functions in patients with various chronic liver diseases

In order to clarify an alteration in thyroid functions in patients with chronic liver diseases, serum total and free thyroxine (T4, FT4), total and free triiodothyronine (T3, FT3), total reverse T3 (rT3), thyrotropin (TSH), thyroxine-binding globulin (TBG) concentrations, and T3 uptake (T3U) were measured by radioimmunoassays in 53 patients with chronic hepatitis (CH), 24 patients with compensated liver cirrhosis (LC), 17 patients with hepatocellular carcinoma associated with LC (HCC), and 40 normal subjects. Serum T4, T3, and rT3 in CH, and serum rT3 in HCC were significantly increased, while serum T4 in LC and serum T3 in HCC were significantly decreased. Serum TBG was increased and T3U was decreased in these patients. Serum TBG in CH and LC correlated positively with transaminase, and inversely with prothrombin time. FT4 and T4/TBG ratios in CH and LC and FT3 and T3/TBG ratios in LC and HCC were significantly decreased. Although T4/TBG ratios in HCC and T3/TBG ratios in CH were significantly decreased, FT4 in HCC and FT3 in CH were not decreased. The ratio of rT3/T3 in CH and LC correlated with various liver function tests. FT3 in LC and HCC correlated inversely with BSP (45') and positively with KICG. No differences in serum TSH values were found between chronic liver diseases and normal subjects. From these results, it was concluded that the thyroid functions in patients with chronic liver diseases were affected by the decrease in serum thyroxine, elevated serum TBG, the degree of which is in proportion to that of the liver cell damage, and impaired peripheral conversion of T4 to T3, the degree of which is in proportion to that of the hepatic dysfunction.     

Central stimulatory effect of leptin on T3 production is mediated by brown adipose tissue type II deiodinase

To assess whether intracerebroventricular leptin administration affects monodeiodinase type II (D2) activity in the tissues where it is expressed [cerebral cortex, hypothalamus, pituitary, and brown adipose tissue (BAT)], hepatic monodeiodinase type I (D1) activity was inhibited with propylthiouracil (PTU), and small doses of thyroxine (T4; 0.6 nmol. 100 g body wt(-1). day(-1)) were supplemented to compensate for the PTU-induced hypothyroidism. Two groups of rats were infused with leptin for 6 days, one of them being additionally treated with reverse triiodothyronine (rT3), an inhibitor of D2. Control rats were infused with vehicle and pair-fed the amount of food consumed by leptin-infused animals. Central leptin administration produced marked increases in D2 mRNA expression and activity in BAT, changes that were likely responsible for increased plasma T3 and decreased plasma T4 levels. Indeed, plasma T3 and T4 concentrations were unaltered by central leptin administration in the presence of rT3. The additional observation of a leptin-induced increased mRNA expression of BAT uncoupling protein-1 suggested that the effect on BAT D2 may be mediated by the sympathetic nervous system.     

Selenium Status Is Positively Associated with Bone Mineral Density in Healthy Aging European Men

ObjectiveIt is still a matter of debate if subtle changes in selenium (Se) status affect thyroid function tests (TFTs) and bone mineral density (BMD). This is particularly relevant for the elderly, whose nutritional status is more vulnerable.ResultsThe overall Se status in our population was low normal with only 0.5% (2/387) of subjects meeting the criteria for Se deficiency. SePP and Se levels were not associated with thyroid stimulating hormone (TSH), free thyroxine (FT4), thyroxine (T4), triiodothyronine (T3) or reverse triiodothyronine (rT3) levels. The T3/T4 and T3/rT3 ratios, reflecting peripheral metabolism of thyroid hormone, were not associated with Se status either. SePP and Se were positively associated with total BMD and femoral trochanter BMD. Se, but not SePP, was positively associated with femoral neck and ward''s BMD. Multivariate linear analyses showed that these associations remain statistically significant in a model including TSH, FT4, body mass index, physical performance score, age, smoking, diabetes mellitus and number of medication use.ConclusionOur study demonstrates that Se status, within the normal European marginally supplied range, is positively associated with BMD in healthy aging men, independent of thyroid function. Thyroid function tests appear unaffected by Se status in this population.     

Measurement of thyroid hormone concentrations in human placenta

Concentrations of thyroxine (T4), 3,5,3'-triiodothyronine (T3) and 3,3',5'-triiodothyronine (rT3) in the placenta were measured in 7 patients with abortion, in 9 patients with premature delivery, in 16 normal pregnancies and in 4 pregnant women with Graves' disease. The placentas, obtained at delivery, were homogenized and centrifuged at 800 X g. T4, T3 and rT3 concentrations in the supernatants were extracted with 3 vol. of 99% ethanol and measured by RIAs. In normal pregnancy, placental T4, T3 and rT3 concentrations were 18.8 +/- 5.9 (mean +/- SD), 0.026 +/- 0.012, and 1.70 +/- 0.49 ng/g tissue, respectively. Ratios of rT3/T3 and rT3/T4 in the placenta were about 12 and 2.3 times as high as those in the fetal sera, respectively. There was a significant positive correlation between the placental T4 and the maternal or cord serum T4 concentrations. However, no correlation was found between the placental T3 or rT3 concentrations and the maternal or cord T3 or rT3 concentrations. In 4 patients with Graves' disease, the placental T4 concentration was elevated. These results indicate that the placental T4 concentration is influenced by both the maternal and fetal serum T4, and elevated ratios of rT3/T3 and rT3/T4 in the placenta might be due to the active placental 5-monodeiodination.     

Decreased ratio of serum T3:rT3 in patients with hyperthyroidism

In 14 hyperthyroid patient serum T4:rT3 ratio was significantly lower (399 +/- 20) than in the control subjects (572 +/- 20; p less than 0.001). A similar pattern was found for serum T3:rT3 ratio. In the hyperthyroid group the ratio was significantly lower (10.5 +/- 0.5) than in the control group (12.5 +/- 0.6; p less than 0.05). The data suggest that in hyperthyroidism the organism might shift conversion of T4 from biologically active T3 to poorly calorigenic rT3. It seems possible that the proportionately increased generation of rT3 than that of T3 may be a defence mechanism of the body, as it was found in systemic illnesses and starvation.     

Nuclear thyroxine and triiodothyronine binding in mononuclear cells in dependence of age

Nuclear binding of thyroxine (T4) and triiodothyronine (T3) in mononuclear blood cells was investigated in 12 young (age 16-30 years) healthy subjects (group A), in 12 middle-aged (age 31-60 years) healthy subjects (group B) and in 12 elderly (61-90 years) healthy subjects. Serum free T3 was depressed in group C as compared to the younger age groups, whereas serum free T4 and TSH did not differ between the groups. Maximal specific nuclear binding capacity for both T4 and T3 decreased with increasing age, T4 group A: 1.2 fmol T4/100 micrograms DNA, group B: 1.2 fmol T4/100 micrograms DNA, group C: 0.7 fmol T4/100 micrograms DNA; T3 group A: 1.7 fmol T3/100 micrograms DNA, group B: 1.0 fmol T3/100 micrograms DNA, group C: 0.9 fmol T3/100 micrograms DNA. The equilibrium association constant (Ka) for T4 increased with age, group A: Ka = 3.3 X 10(9) l/mol, group B: Ka = 3.2 X 10(9) l/mol, group C: Ka = 6.4 X 10(9) l/mol, whereas Ka for nuclear binding of T3 decreased with age group A: Ka = 3.9 X 10(9) l/mol, group B: Ka = 5.9 X 10(9) l/mol, group C: Ka = 1.8 X 10(9) l/mol. We conclude that, whereas the opposite variations of nuclear capacity and binding affinity for T4 tend to preserve the nuclear T4 concentration, the nuclear T3 concentration definitely decreases with age. The unaltered serum levels of TSH suggest that the decrease of both serum levels of free T3 and the nuclear T3 concentration might represent physiologically changes in old age.