In order to assess iodothyronine receptor interactions in man, we have developed a receptor assay for T3 and T4 in solubilized nuclear extracts from circulating mononuclear cells. This assay utilizes the technique of salt solubilization to isolate nuclear receptors and employs standard saturation analysis for T3 and T4 to determine maximal binding capacity (MBC) and equilibrium dissociation constants (Kd). We have determined that 11 normal subjects had a MBC for T3 of 1.20 +/- 0.20 pmol/mg DNA (+/- SE) and a Kd of 3.4 +/- 0.2 X 10(-10) M; the T4 MBC was 8.44 +/- 1.22 pmol/mg DNA and the Kd was 2.7 +/- 0.3 X 10(-10) M. Hypothyroid patients had a mean T3 MBC of 7.32 +/- 2.28 pmol/mg DNA and a mean T4 MBC of 40.04 +/- 21.36 pmol/mg DNA (P less than 0.05 compared to normal). Obese subjects (n = 12) had a basal fed MBC that was 0.66 +/- 0.13 pmol/mg DNA for T3 (P less than 0.05 compared to normal) and was 3.58 +/- 0.56 pmol/mg DNA for T4 (P less than 0.01 compared to normal). During fasting, the average T3 MBC increased to 1.43 +/- 0.31 pmol/mg DNA and the average T4 MBC increased to 9.63 +/- 2.46 pmol/mg DNA, values that are both significantly higher than those in the fed period; the dissociation constants were unaltered in obese subjects (compared to normals) in fed and fasting states. Gel filtration with 0.5 M agarose was employed to ascertain if the physicochemical properties of the solubilized mononuclear human cell receptor were similar to those previously observed in rat and human liver and kidney receptors. The elution profile obtained was similar to that reported earlier. The major binding activity has an estimated Stokes radius of 35 A and a molecular weight ratio of approximately 50,000 daltons. These studies indicate that: 1) high affinity T3 and T4 receptors exist in human mononuclear cells and have properties similar to those for T3 and T4 described previously in rat liver; 2) T3 and T4 receptor number tends to increase in hypothyroid subjects and tend to be lower in obese patients than in normal weight control subjects; 3) fasting is associated with an increase in both T3 and T4 MBC; and 4) despite their apparent physicochemical similarity, T3 receptors in rat liver and human mononuclear cells may be regulated differently, at least during fasting since hepatic T3 receptors decrease in the fasted rat. Collectively, these observations support the concept that human white cell T3 nuclear receptor binding is capable of rapid fluctuations, suggesting a mechanism for homeostatic regulation of T3 action.
Triiodothyronine (T3) receptor kinetics were determined in liver nuclei isolated from fasting and fed rats. The results indicate that although affinity equilibrium constants (Ka) did not differ in the two groups, mean (+/- SE) maximal binding capacity (MBC) was reduced significantly to .30 +/- .05 nM/mg DNA in fasting compared to .46 +/- .07 nM/mg DNA (p less than .01) in the fed state. This observed decrease in MBC during fasting apparently could not be accounted for by a differential rates of loss of either DNA or of the receptor during the period of incubation.
Human lymphocytes are known to play a critical role in autoimmune diseases both by producing antibodies and by participating in lymphokine-cellular interactions. TSH, a classic pituitary hormone, may be secreted by human lymphocytes, and controversy has existed whether a specific, authentic TSH receptor also was present on the surface of these cells. The objective of our study was to identify TSH receptor transcripts after designing specific oligonucleotides that would recognize a unique putative TSH binding area of the thyroidal TSH receptor. The existence of TSH receptor transcripts was probed by employing these primers in a PCR reaction with cDNA derived from normal peripheral human lymphocytes and human thyroid tissue, as well as with cDNA from a medullary cancer cell line and rat liver. Human lymphocytes and thyroid tissue, but not medullary cancer cells or rat liver, demonstrated specific TSH receptor amplification product both by ethidium bromide staining and by Southern blot hybridization with labeled TSH receptor cDNA. The lymphocyte cDNA was partially sequenced and found to be identical to the thyroid-derived cDNA. These findings indicate that normal, nonactivated, human lymphocytes produce transcript for a TSH receptor that appears identical to that in thyroid tissue. Future studies should focus on the regulation of this transcript, as well as on the role TSH and TSH receptor may play in modulating local lymphokine activation of T and B cells, both in normal conditions and in autoimmune thyroid disease.
RNA was isolated from fibroblasts from the retroocular area, from endomysial fibroblasts obtained from orbital lateral rectus muscle, and from abdominal skin fibroblasts. The RNA was reverse transcribed into cDNA which was then used as a template for PCR with primers encompassing a portion (nucleotides 989-1235) of the extra-cellular domain of the human TSH receptor (hTSH-R). A definite 247 BP product was detected from fibroblast RNA by ethidium bromide staining, and was confirmed by hybridization with labelled hTSH-R cDNA. The product had homology with the known TSH-R cDNA. These studies indicate that human fibroblasts can express hTSH-R, and they suggest that a cross reactive immunologic response between anti-hTSH-R and these fibroblast TSH receptors may play a role in the genesis of Graves' ophthalmopathy.
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