We report an improved heterologous radioimmunoassay (RIA) for the measurement of thyrotropin (TSH) in mouse serum. The assay components are: antirat thyrotropin (rTSH) serum from the National Hormone and Pituitary Program, a commercial [125I]-labeled rTSH and mouse thyrotropin (mTSH) serum standards produced by dilution of a serum pool from hypothyroid mice with high TSH with a serum pool from mice treated with excess levothyroxine (LT4) (mTSH-0). Sensitivity was increased by reducing the amount of antibody and tracer and by taking advantage of the disequilibrium technique. Accuracy was greatly improved by the preparation of mouse serum TSH standards. TSH in serial dilutions of individual mice with high TSH of different etiologies paralleled the mTSH standard curve but not that of rTSH or a crude mouse TSH/luteinizing hormone (LH) reference preparation. The high-mTSH-serum standard contained 20 mU TSH per milliliter, measured in a bioassay utilizing a cell line stably transfected with human TSH receptor cDNA, and a relative TSH concentration of 40 ng/mL. The sensitivity of the RIA is 0.01 to 0.02 ng/mL, depending on the quality of the tracer and the preparation of mTSH-0 serum. The intra-assay and interassay coefficients of variations were, respectively: 16% and 27% at 0.04 ng/mL; 6.3% and 8.2% at 0.4 ng/mL; 5.4% and 9.8% at 1.7 ng/mL; 10% and 24% at 4.0 ng/mL. The mean TSH concentration in serum of 60-80-day-old male mice was four-fold higher than that in females of the same age. The assay was able to distinguish differences in serum TSH concentrations in five different strains of mice. Baseline serum TSH concentrations (mean +/- SD) of 70-day-old male mice were: 0.143 +/- 0.065 ng/mL in the CD-1 strain; 0.229 +/- 0.042 ng/mL in C57BL/6 mice; 0.084 +/- 0.017 ng/mL in SWR/J mice; 0.133 +/- 0.057 ng/mL in NOD SCID mice, and 0.266 +/- 0.122 ng/mL in FVB mice. Mean serum thyroxine (T4) concentrations were also significantly different among the mouse strains but did not correlate with the serum TSH level. Administration of levotriiodothyronine (LT3) suppressed the serum TSH to a greater degree in mice with higher baseline TSH values. Suppression of the thyroidal radioiodide uptake with LT3 correlated with that of serum TSH.
Only three of the four thyroid hormone receptor (TR) isoforms, alpha1, beta1, and beta2, bind thyroid hormone (TH) and are considered to be true TRs. TRalpha2 binds to TH response elements on DNA, but its role in vivo is still unknown. We produced mice completely deficient in TRalpha (TRalpha(o/o)) that maintain normal serum thyroid-stimulating hormone (TSH) concentration despite low serum thyroxine (T(4)), suggesting increased sensitivity to TH. We therefore examined the effects of TH (L-3,3',5-triiodothyronine, L-T3) given to TH-deprived and to intact TRalpha(o/o) mice. Controls were wild-type (WT) mice of the same strain and mice resistant to TH due to deficiency in TRbeta (TRbeta(-/-)). In liver, T3 produced significantly greater responses in TRalpha(o/o) and smaller responses in TRbeta(-/-) as compared with WT mice. In contrast, cardiac responses to L-T3 were absent or reduced in TRalpha(o/o), whereas they were similar in WT and TRbeta(-/-) mice, supporting the notion that TRalpha1 is the dominant TH-dependent TR isoform in heart. 5-Triiodothyronine (L-T3) given to intact mice produced a greater suppression of serum T(4) in TRalpha(o/o) than it did in WT mice and reduced by a greater amount the TSH response to TSH-releasing hormone. This is an in vivo demonstration that a TR deficiency can enhance sensitivity to TH. This effect is likely due to the abrogation of the constitutive "silencing" effect of TRalpha2 in tissues expressing the TRbeta isoforms.
We investigated the effect of thyroid hormone (TH) receptor (TR)alpha and -beta isoforms in TH action in the heart. Noninvasive echocardiographic measurements were made in mice homozygous for disruption of TRalpha (TRalpha(0/0)) or TRbeta (TRbeta(-/-)). Mice were studied at baseline, 4 wk after TH deprivation (using a low-iodine diet containing propylthiouracil), and after 4-wk treatment with TH. Baseline heart rates (HR) were similar in wild-type (WT) and TRalpha(0/0) mice but were greater in TRbeta(-/-) mice. With TH deprivation, HR decreased 49% in WT and 37% in TRbeta(-/-) mice and decreased only 5% in TRalpha(0/0) mice from baseline, whereas HR increased in all genotypes with TH treatment. Cardiac output (CO) and cardiac index (CI) in WT mice decreased (-31 and -32%, respectively) with TH deprivation and increased (+69 and +35%, respectively) with TH treatment. The effects of CO and CI were blunted with TH withdrawal in both TRalpha(0/0) (+8 and -2%, respectively) and TRbeta(-/-) mice (-17 and -18%, respectively). Treatment with TH resulted in a 64% increase in LV mass in WT and a 44% increase in TRalpha(0/0) mice but only a 6% increase in TRbeta(-/-) mice (ANOVA P < 0.05). Taken together, these data suggest that TRalpha and TRbeta play different roles in the physiology of TH action on the heart.
Thyroid hormone responsive genes can be both positively and negatively regulated by thyroid hormone. TSH is down-regulated by thyroid hormone and rises during thyroid hormone deprivation. Because both thyroid hormone receptor (TR) alpha and beta genes are expressed in the pituitary gland, it is unclear what the relative roles of TR alpha and TR beta are in TSH regulation. Experiments using over expression of artificial genes have yielded conflicting results. The TR beta knock-out mouse that lacks both TR beta1 and TR beta2 isoforms provides a model to examine the role of these receptors in TSH regulation. TR beta deficient (TR beta-/-) and wild-type (TR beta+/+) mice of the same strain were deprived of thyroid hormone by feeding them a low iodine diet containing propylthiouracil and were then treated with different doses of L-T3 and L-T4. Thyroid hormone deprivation rapidly increased the serum TSH level in both TR beta+/+ and TR beta-/- mice, reaching a similar level in the absence of thyroid hormone. In contrast, the decline of serum TSH by treatment with both L-T3 and L-T4 was severely blunted in TR beta-/- mice, and full suppression was not achieved with the maximal L-T3 dose of 25 microg/day x mouse. These data indicate that TR beta is not required for the up-regulation of TSH in thyroid hormone deficiency. However, although TR alpha alone can mediate thyroid hormone induced TSH suppression, TR beta enhances the sensitivity of TSH down-regulation and may be essential for the complete suppression of TSH.
The maintenance of thyroid hormone (TH) homeostasis is dependent on the synthesis and secretion of TH regulated by TSH. This is achieved, in turn, by the negative feedback of TH on TSH secretion and synthesis, which requires the interaction with TH receptors (TRs). Derived by alternative splicing of two gene transcription products, three TRs (TR 1, TR 2 and TR 1) interact with TH while another, TR 2, binds to DNA but not to TH. In this study we compare the results of thyroid function tests in mice with deletions of the TR and TR genes alone and present novel data on mice that are double homozygous and combined heterozygous. Homozygous deletions of both the TR and TR in the same mouse (TR o/o; TR / ) resulted in serum TSH values only slightly lower than those in athyreotic, Pax8 knockout mice. Whereas the absence of TR alone does not cause resistance to TH, the absence of TR in the presence of TR results in a 205, 169, 544% increase in serum thyroxine (T 4 ), triiodothyronine (T 3 ) and TSH concentrations respectively. However, in the absence of TR , loss of one TR allele can worsen the resistance to TH with a 243 and 307% increase in T 4 and T 3 respectively. Similarly, while the heterozygous mouse with a single TR allele shows no alteration in thyroid function, the concomitant deletion of TR brings about mild but significant resistance to TH. Furthermore, the severity of the resistance to TH was noted to decrease with age in parallel with the decrease in serum free T 4 values also seen in wild-type mice. These results demonstrate that (1) unliganded TR or TR are not absolutely necessary for the upregulation of TSH; (2) TR but not TR is sufficient for TH-mediated downregulation of TSH; and (3) TR may partially substitute for TR in mediating a partial TH-dependent TSH suppression.
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