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The Thyroid Hormone Receptor-ß Gene Mutation R383H Is Associated with Isolated Central Resistance to Thyroid Hormone¹

Thyroid Unit (J.D.S., F.E.W.) and the Division of Behavioral Neurology (M.G.O.), Beth Israel Deaconess Medical Center and Harvard Medical School, Boston, Massachusetts 02215; the Division of Cardiology, Children’s Hospital and Harvard Medical School (S.D.C., S.S.), Boston, Massachusetts 02194; and the Division of Endocrinology and Metabolism, Winthrop University Hospital and State University of New York School of Medicine (S.R.T.), Mineola, New York 11501

Address all correspondence and requests for reprints to: Joshua D. Safer, M.D., Section of Endocrinology, Nutrition, and Diabetes, Boston, University School of Medicine, Room M-958, 715 Albany Street, Boston, Massachusetts 02118. E-mail: Jsafer{at}bu.edu

	Abstract

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Resistance to thyroid hormone (RTH) action is due to mutations in the ß-isoform of the thyroid hormone receptor (TR-ß). RTH patients display inappropriate central secretion of TRH from the hypothalamus and of TSH from the anterior pituitary despite elevated levels of thyroid hormone (T₄ and T₃). RTH mutations cluster in three hot spots in the C-terminal portion of the TR-ß. Most individuals with TR-ß mutations have generalized resistance to thyroid hormone, where most tissues in the body are hyporesponsive to thyroid hormone. The affected individuals are clinically euthyroid or even hypothyroid depending on the severity of the mutation. Whether TR-ß mutations cause a selective form of RTH that only leads to central thyroid hormone resistance is debated. Here, we describe an individual with striking peripheral sensitivity to graded T₃ administration. The subject was enrolled in a protocol in which she received three escalating T₃ doses over a 13-day period. Indexes of central and peripheral thyroid hormone action were measured at baseline and at each T₃ dose. Although the patient’s resting pulse rose only 11% in response to T₃, her serum ferritin, alanine aminotransferase, aspartate transaminase, and lactate dehydrogenase rose 320%, 117%, 121%, and 30%, respectively. In addition, her serum cholesterol, creatinine phosphokinase, and deep tendon reflex relaxation time fell (25%, 36%, and 36%, respectively). Centrally, the patient was sufficiently resistant to T₃ that her serum TSH was not suppressed with 200 µg T₃, orally, daily for 4 days. The patient’s C-terminal TR exons were sequenced revealing the mutation R383H in a region not otherwise known to harbor TR-ß mutations. Our clinical evaluation presented here represents the most thorough documentation to date of the central thyroid hormone resistance phenotype in an individual with an identified TR-ß mutation.

	Introduction

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RESISTANCE to thyroid hormone (RTH) is the result of mutations in the carboxyl-terminus of the ß-thyroid hormone receptor (TR-ß) (1, 2, 3, 4). Individuals with the disorder require greater thyroid hormone (T₃) concentrations to achieve T₃-dependent actions. RTH is a dominant disorder (except in one patient) in which most individuals are heterozygous for the mutant allele. In a phenomenon called dominant negative activity, the mutant allele interferes with the activity of the normal allele (5, 6, 7, 8). RTH mutations cluster in three hot spots in the TR-ß (9, 10, 11, 12).

Clinically, RTH can be divided into two entities: generalized resistance to thyroid hormone (GRTH) and central resistance to thyroid hormone (CRTH) (4). In both syndromes there is thyroid hormone resistance at the level of the pituitary and hypothalamus, causing inappropriate TSH secretion and, in turn, elevated thyroid hormone levels. In GRTH there is also peripheral resistance, often resulting in a hypothyroid- or euthyroid-appearing patient (13). In CRTH, however, peripheral sensitivity to thyroid hormone is preserved, and the individual suffers thyrotoxic symptomatology from the elevated levels of circulating T₃ (14). Previously, patients with CRTH were referred to as having pituitary resistance to thyroid hormone. Recent studies suggest, however, that both hypothalamic resistance and pituitary resistance are required to significantly raise thyroid hormone levels (15); therefore, our laboratory believes a more suitable term for this disorder is CRTH.

Many researchers maintain that both GRTH and CRTH are part of a spectrum of the same genetic disorder (9, 16, 17). This can be explained because the CRTH phenotype is not clearly defined in patients with a rigorous clinical evaluation. Based on newer information, we and others have concluded that GRTH and CRTH represent distinct disorders (18, 19). Individuals are often assigned the GRTH or CRTH designation based on resting pulse measurements or other parameters in the absence of T₃ suppression testing. As the effects of thyroid hormone on the heart may be predominantly mediated by TR-, this defining characteristic may not be suitable to separate these disorders (20).

Refetoff et al. used a T₃ suppression protocol to distinguish GRTH individuals from normal subjects (4, 21). We have established a similar protocol to separate CRTH individuals, GRTH individuals, and normal subjects. We have begun to collect data on individuals with rigorously defined CRTH using our protocol (22). Here we present the most rigorous evaluation of an individual with CRTH to date.

	Materials and Methods

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Clinical evaluation

For clinical evaluation, the subject was admitted to the Beth Israel Deaconess Medical Center (BIDMC) General Clinical Research Center in Boston, MA. A protocol to evaluate patients with CRTH was approved by our institutional review board. Serum, urine, and other testing was performed at baseline. Subjects then commenced graded thyroid hormone (oral T₃) administration as follows: 25 µg twice daily for 4 days, 50 µg twice daily for 4 days, and 100 µg twice daily for 4 days. All testing was repeated on the morning before each dose change.

On day 0, the subject was admitted to the General Clinical Research Center at BIDMC. On day 1, baseline evaluation was undertaken, including serum chemistries, thyroid function tests, urine studies, ankle jerk relaxation time measurement, TRH stimulation, resting cardiac evaluation, and psychological evaluation. The subject then began taking 25 µg T₃ twice daily. On day 5, the parameters measured at baseline were remeasured. The T₃ dose was raised to 50 µg twice daily, and the parameters were remeasured on day 9. Finally, the T₃ dose was raised to 100 µg twice daily, and the parameters were measured a final time on day 13.

Indexes of peripheral thyroid hormone action were chosen to include tests that are routinely performed and tests that measure signs associated with abnormal thyroid hormone levels. To these ends serum tests included ferritin, sex hormone-binding globulin (SHBG), alanine aminotransferase (ALT), aspartate transaminase (AST), creatinine phosphokinase (CK), lactate dehydrogenase (LDH), total cholesterol, and fasting triglycerides.

Evaluation of central T₃ action

On each testing day, baseline serum TSH was measured using a third generation TSH assay (sensitivity, 0.01 µU/mL; interassay coefficient of variation, 5%). In addition, each subject underwent a TRH stimulation test to assess further the degree of central resistance. Subjects received 7 µg/kg BW (but never more than 500 µg) protirelin (Ferring Pharmaceuticals Ltd., Suffern, NY) by iv push. Serum TSH and PRL were measured at baseline and 15, 30, 45, 60, 90, 120, and 180 min after receiving the TRH dose.

Evaluation of peripheral T₃ action

On each study day, indexes of peripheral thyroid hormone activity were measured. Serum ALT, AST, ferritin, SHBG, cholesterol, and triglycerides were measured to determine the effect of T₃ on metabolic and hepatic functions. All samples were gathered in the morning after an overnight fast. An overall assessment of relative peripheral thyroid hormone effect was made with the diagnostic index developed by Billewicz et al. (23). A weight measurement was made each study day as well.

To assess neuromuscular impact from thyroid hormone, serum CK and ankle jerk relaxation time were assessed. To obtain accurate and reproducible ankle jerk relaxation times, a high speed camera was used to film the entire reflex at each dose. The camera was programmed to track movements of the subject’s foot at 16.7-ms intervals. For increased precision of the test, the time from peak to half-maximum was measured. At each dose, five measurements were made and averaged. In normal individuals, no significant change in relaxation time was observed despite large variations in the strength and speed of reflex hammer blows.

Basal cardiac status was assessed with an echocardiogram and a sleeping heart rate measurement. Subjects were attached to a remote cardiac monitor, and minute long samples of heart rates were recorded during each hour of nighttime sleep. In the morning, an average of the samples was taken.

The echocardiographic evaluation consisted of two-dimensional and Doppler evaluation, with analysis of the stress-velocity and stress-shortening indexes (24). Two-dimensional and Doppler echocardiographies were performed for the qualitative assessment of regional wall motion, the presence of intracardiac thrombus, and evidence of valvular heart disease. An m-mode echocardiogram directed by two-dimensional imaging was recorded simultaneously with an electrocardiogram, phonocardiogram, and carotid pulse tracing. Blood pressure was measured with a Critikon automated vital signs monitor (Johnson and Johnson Company, Tampa, FL). The m-mode echocardiogram, phonocardiogram, and pulse tracing were analyzed by computer as previously described (24). End-diastolic dimension and wall thickness were taken as the measures of left ventricular size, fractional shortening was used as the index of global ventricular function, wall stress was determined as the index of afterload, and the afterload-adjusted velocity of shortening (stress-velocity index) was obtained as the index of contractility.

Neuropsychological evaluation

The subject was seen for neuropsychological testing on each of the study days. Tests focused on various aspects of attention (attention span, speed of processing, sustained attention, and selective attention) and memory. Tests that were resistant to practice effects or that had alternate forms available were chosen. To these ends, tests used included the Digit Span and Digit Symbol subtests from the Wechsler Adult Intelligence Scale-Revised (25), the Trailmaking-B test (26), the Paced Auditory Serial Addition Test (27), and the Auditory Verbal Learning Test (AVLT) (28). Testing was conducted by an examiner blind to the subject’s diagnosis.

Sequencing of DNA

DNA was extracted from whole blood using the G NOME Whole Blood Kit (BIO 101, Inc., Vista, CA). With intronic primers (29), the carboxyl-terminal exons 5, 6, 7, and 8 (formerly exons 7, 8, 9, and 10) of the TR-ß were amplified by PCR. The amplified exons were subcloned into the bacterial plasmid vector pGEM T (Promega Corp., Madison, WI). Subclones were sequenced with T7 Sequenase 2.0 (Amersham Pharmacia Biotech, Cleveland, OH).

	Results

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The propositus, presenting with thyrotoxic symptoms and an inappropriately elevated TSH, was diagnosed with CRTH

A 54-yr-old white woman was referred for inappropriately elevated TSH levels. The woman reported a 20-yr history of palpitations and anxiety. She suffered spontaneous palpitations three to four times weekly and sought emergency room evaluation on several occasions. Approximately 10 yr before presentation, the woman was diagnosed with Graves’ disease and was treated twice with ¹³¹I. The woman then enjoyed a long period of "tolerable" palpitations that were treated with ß-blockers on occasion. A physician viewing her laboratory tests treated her with levothyroxine. The woman reported no impact on her symptoms from the levothyroxine treatment.

On presentation, the woman was taking 50 µg/day levothyroxine. Her laboratory thyroid testing at this time revealed a serum TSH of 14.8 µU/mL (normal, 0.35–5.5) with a free T₄ index of 4.6 (normal, 1.6–3.7). Off levothyroxine, the woman was noted to have a serum TSH of 17.6, a free T₄ by equilibrium dialysis of 0.8 ng/dL (normal, 0.8–2.7), and a free T₃ by equilibrium dialysis of 420 pg/dL (normal, 260–480). Her glycoprotein hormone -subunit level and pituitary magnetic resonance imaging were normal. She had no other medical problems. The woman had a normal thyroid exam. The remainder of her physical exam was normal, except for obesity (26% above ideal body weight) and a resting tremor.

Available family consisted of an affected sister and a normal brother

The propositus was one of four children of nonconsanguinous parents (Fig. 1). The father had no record of thyroid disease. The mother reportedly suffered hyperthyroidism, which required two rounds of radioactive iodine to treat. Both parents are deceased. Of the three siblings, one died accidentally at age 7 yr, and the remaining two were available for further study. At the time of the evaluation, the brother was 58 yr old and had no history of thyroid disease. He was healthy, and his thyroid function tests were as follows: TSH, 2.96 µU/mL; free T₄ by equilibrium dialysis, 1.5 ng/dL (normal, 0.9–2.0); and free T₃ by equilibrium dialysis, 2.2 pg/mL (normal, 2.0–4.0). The brother was the only sibling with natural children, and both children were healthy.

View larger version (11K): [in this window] [in a new window]   Figure 1. Pedigree of the CRTH kindred with an R383H mutation.

Sequencing the C-terminus of the TR-ß of the propositus and her family revealed a mutation at amino acid 383

We isolated genomic DNA from the buffy coat of a whole blood sample from the propositus. Carboxyl-terminus exons were amplified by PCR, subcloned into the pGEM T vector, and sequenced. By this method an arginine to histidine mutation was found in amino acid 383 (Fig. 2). The remainder of the C-terminus was free of mutations. The R383H mutation has been reported once before (19) in a patient believed to suffer CRTH. Amino acid 383 is of interest in that it lies in a region not previously thought to contain resistance mutations. In the crystal structure of the rat TR- (30), residues homologous to R383 and the previously described CRTH amino acid, R429, may interact with amino acids homologous to E311 and D382 to form a salt bridging group in a polar invagination. These residues may define a domain important in negative transcriptional regulation by TR.

View larger version (36K): [in this window] [in a new window]   Figure 2. Location of the R383H TR-ß point mutation in a patient with CRTH. The wild-type (WT) sequence of the TR-ß amino acid 383 (CGC; bold) and adjacent amino acids is shown on the left. On the right is the sequence of an affected subject’s mutant allele across the same area (R383H, CGC to CAC).

The propositus (C23) was enrolled in a protocol to evaluate relative central and peripheral sensitivity to thyroid hormone: she was profoundly resistant to T₃ centrally

Six months after cessation of all exogenous thyroid medication, the propositus (C23) was enrolled in the clinical resistance to thyroid hormone protocol at BIDMC. To facilitate broad comparisons with historical data, the protocol was written as a modification of the protocol used by Refetoff et al. (4). C23 began the study with TSH elevated to 15.4 µU/mL despite high normal total thyroid hormone levels (T₄, 10.0 µg/dL; T₃, 136 ng/dL). More striking, C23’s basal TSH remained detectable throughout the study. On the medium and high T₃ doses, both our normal patient and historical normal controls (21) had completely suppressed TSH. When C23 took 200 µg T₃ daily for 4 days, her TSH could still be measured (Fig. 3).

View larger version (27K): [in this window] [in a new window]   Figure 3. Central thyroid hormone action was evaluated with a TRH stimulation test at each T3 dose. Sample times after TRH injection are indicated on the x-axis. TSH values are indicated on the y-axis. The left column of graphs represents the results from a normal individual, and the right column of graphs represents the results from a CRTH individual with the R383H TR-ß mutation. Although the normal subject’s TSH levels were suppressed with 50 µg T3 daily, the CRTH subject’s TSH levels failed to be suppressed completely even with 200 µg T3 daily. Insets amplify the y-axis scale for the normal individual. Note that the normal subject’s values on the medium and high T3 doses include significant scatter around the detection limit of the assay.

RTH patients are separated from hypothyroid patients by their PRL responses to TRH stimulation. C23’s basal PRL level was 4.3 ng/mL (normal, 2–14). Her TRH-stimulated PRL rise to a peak of 38 was normal and only 30% of that seen in patients with hypothyroidism (21, 31, 32). C23’s TRH-stimulated PRL fell to 42% and 29% of her baseline TRH-stimulated PRL on the medium and high T₃ doses, respectively (Fig. 4). This did not separate her from our normal subject, whose TRH stimulated PRL suppressed to 52% and 48% of baseline TRH-stimulated PRL on those T₃ doses (Fig. 4). The TRH-stimulated PRL in our GRTH subject was suppressed to 36% and 32% of baseline TRH-stimulated PRL on the respective medium and high T₃ doses. Thus, we could not distinguish normal, CRTH, and GRTH individuals by observing their TRH-stimulated PRLs.

View larger version (19K): [in this window] [in a new window]   Figure 4. The PRL response to TRH stimulation was measured at each T3 dose. Sample times after TRH injection are indicated on the x-axis. PRL values are indicated on the y-axis. The left column of graphs represents the results from a normal individual, and the right column of graphs represents the results from a CRTH individual with the R383H TR-ß mutation. Both the normal subject and the CRTH subject had normal PRL responses to TRH initially. As the T3 dose escalated, both subjects had similar declines in their peak stimulated PRLs.

A synthesized diagnostic index of relative peripheral thyroid hormone action was designed by Billewicz et al. (23) to assess hypo- and hyperthyroidism before the advent of good clinical chemistry tests. We used the diagnostic index from Billewicz on each study day. Indeed, over the course of the evaluation, C23’s diagnostic index rose 179%, reflecting greater peripheral T₃ sensitivity than that of a normal individual similarly assessed (Fig. 5A). The normal subject noted only a 33% rise. The GRTH subject, by contrast, reported a paradoxical decline.

View larger version (25K): [in this window] [in a new window]   Figure 5. Two systemic indexes of T3 action were evaluated, Billewicz diagnostic index (A) and weight (B). The stippled bars indicate the change from baseline evaluation when the individual was taking 100 µg T3 daily. The solid bars indicate the change from baseline when the individual was taking 200 mg T3 daily. Bars on the historical data represent the SEM. In contrast to the weight stability demonstrated by the GRTH subjects, the R383H subject demonstrated normal weight loss in response to T3 administration. Also, the R383H subject demonstrated a supernormal rise in diagnostic index as the T3 dose rose.

As a surrogate for energy consumption, weight was determined on each study day. Despite a concerted effort to maintain isocaloric diets before and during the study, C23 lost 3% of her body weight between the baseline measurement and that on the high dose of T₃ (Fig. 5B). This proved consistent with the experience of our normal subject and the historical normal subjects (4). It contrasted with our GRTH subject and the historical GRTH subjects whose weights remained remarkably stable after T₃ administration.

C23 demonstrated marked hepatic sensitivity to T₃

C23’s hepatic sensitivity was demonstrated via several common chemistry tests reflective of liver biosynthetic activity. Our studies included the standard liver function tests, ALT and AST. Products of liver metabolism, such as cholesterol and SHBG, and the acute phase reactant, ferritin, were measured. Refetoff et al. (4) used the above parameters in their similar studies of GRTH patients and normal subjects. Although tests in normal patients demonstrated sensitivity to administered thyroid hormone, GRTH patients demonstrated striking stability of these T₃-sensitive parameters even at the highest daily dose (Fig. 6).

View larger version (75K): [in this window] [in a new window]   Figure 6. To evaluate hepatic metabolism in response to T3, fasting serum evaluations were made at baseline and then on each T3 dose. The stippled bars indicate the change from baseline evaluation when the individual was taking 100 µg T3 daily. The solid bars indicate the change from baseline when the individual was taking 200 µg T3 daily. To facilitate contrast with the historical data, the SHBG change is noted in nanomoles per L rather than as a percentage. Bars on historical data indicate the SEM. In contrast to the stability seen with GRTH patients, the R383H subject demonstrated normal or supernormal responses when ferritin (A), SHBG (B), total cholesterol (C), and triglycerides (D) were measured. Similarly, the R383H subject demonstrated normal or supernormal responses when ALT (E) and AST (F) were measured.

Neuromuscular indexes were also dramatically altered by T₃ administration

Neuromuscular activity is considered sensitive to changes in thyroid hormone levels in normal individuals. To assess the impact of our T₃ protocol, we checked serum CK and measured the ankle jerk relaxation time at each dose. To avoid the error introduced by a roving baseline in ankle jerk relaxation time measurement, the time from peak to half-maximum relaxation was used. Like that of normal individuals and in contrast to that of GRTH individuals, C23’s serum CK fell 36% (Fig. 7A) over the course of the study. Although there is no quantitative assessment of ankle jerk reflex in GRTH patients receiving T₃, attempts have been made to quantify ankle jerk relaxation times in euthyroid and hyperthyroid individuals (33, 34, 35, 36). In these studies, the hyperthyroid relaxation times averaged 20% faster than the euthyroid relaxation times. Our normal subject exhibited a 15% fall in Achilles tendon relaxation time with the 200 µg/day T₃ dose (Fig. 7B). By these criteria, the CRTH subject exhibited a supernormal decline in Achilles tendon relaxation time (36%) while taking 200 µg T₃ daily (Fig. 7B).

View larger version (25K): [in this window] [in a new window]   Figure 7. To evaluate the neuromuscular response to T3, serum CK (A) and ankle jerk relaxation time (B) measurements were made at baseline and then on each T3 dose. The stippled bars indicate the change from baseline evaluation when the individual was taking 100 µg T3 daily. The solid bars indicate the change from baseline when the individual was taking 200 mg T3 daily. Bars on the historical data represent the SEM. In B, SEM measurements are those derived from the five repetitions of each test. The R383H subject demonstrated normal or supernormal responses.

Cardiac function was not associated with other peripheral indicators. Although the sleeping heart rate of C23 rose with her dose of T₃, the degree of rise was less than that in either normal or GRTH subjects (Fig. 8). Further confounding matters, our normal subject’s heart rate proved more resistant to T₃ administration than in the normal subjects reported by Refetoff et al., but was statistically equivalent to values in the historical GRTH patients receiving 200 µg T₃ daily.

View larger version (31K): [in this window] [in a new window]   Figure 8. To evaluate the cardiac response to T3, sleeping heart rate was measured at baseline and then on each T3 dose. The stippled bars indicate the change from baseline evaluation when the individual was taking 100 µg T3 daily. The solid bars indicate the change from baseline when the individual was taking 200 mg T3 daily. Bars on the historical data represent the SEM. In contrast to the other peripheral thyroid hormone action indexes measured, the CRTH subject’s heart rate proved more stable to T3 stimulation than did the heart rates of normal and GRTH subjects.

Although C23’s myocardial contractility was increased on the highest T₃ dose, this did not represent a significant change, and the measurement remained within normal limits. Using our stress-velocity index as an index of contractility, C23 demonstrated a 23% increase in contractility from the baseline to the highest T₃ dose. Our one normal individual demonstrated a 9% increase, and our GRTH subject demonstrated a 19% increase over the same interval. All of these changes were within the measurement error of the test itself, and all of the contractility values were within previously determined normal limits (24).

C23 exhibited improved neuropsychological conditioning in response to higher T₃ doses

Although neuropsychological tests were chosen in which normal individuals would not be expected to improve over several repetitions, C23’s performance on tests of attention span, speed of processing, selective attention, mental flexibility, verbal learning (memory), and motor speed improved as her dose of T₃ was raised. A test of attention span revealed a 33% improvement from baseline to the 200 µg T₃ test day. The degree of change proved more dramatic than the small 6% improvement seen in our normal subject over the same period. On the test of speed of processing and selective attention (Paced Auditory Serial Addition Test), C23’s baseline score fell in the low range (20th percentile). Her performance on this test rose steadily across subsequent sessions, such that it was in the high range (80th percentile) by the 200 µg T₃ test day. A similar rate and extent of improvement was noted on the test of mental flexibility (Trailmaking-B). At baseline, C23’s performance was at the 75th percentile. On high dose T₃, her performance rose to the 90th percentile for the test. Our normal subject suffered a small deterioration in score over the same time period. C23’s performance on the verbal learning test (AVLT) revealed steady improvement as the T₃ dose escalated. Initially, her learning was average (50th percentile). By the high T₃ dose, her recall rose to the 90th percentile. Delayed recall also improved from baseline (30th percentile) to the high T₃ dose (70th percentile). On the AVLT, too, C23 proved more sensitive to T₃ than the normal subject, who demonstrated no change in score over the course of the protocol. Finally, on the test of motor speed, C23’s score rose from the 25th percentile initially to the 75th percentile on high dose T₃. This also was quite dramatic. The normal subject tested exhibited a rise from the 9th percentile to the 25th percentile over the protocol for a similar fold improvement.

	Discussion

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In this report we have identified the R383H substitution mutation in the TR-ß gene of a woman with RTH. Our rigorous evaluation revealed that although the subject suffered profound thyroid hormone resistance centrally, she was quite sensitive to thyroid hormone peripherally. Our study represents the most thoroughly evaluated CRTH individual to date. In our analysis we agree with the position of Clifton-Bligh et al. (19) that the R383H TR mutation is associated with CRTH. In addition, we expand the clinical documentation to include a comprehensive stimulated physiological examination.

Several observations are worthy of highlight. First, the existence of a discreet CRTH clinical entity is much debated. Refetoff et al. (4, 21) designed a protocol of escalating T₃ administration to separate normal and GRTH individuals. In that study, individuals defined as having RTH were found to demonstrate relatively nonsuppressed TSH levels despite high doses of exogenous T₃. Normal subjects in the same study had their TSH levels suppressed at significantly lower T₃ doses. When parameters of peripheral thyroid hormone action were evaluated, the RTH subjects exhibited no change or even paradoxical responses in the face of high T₃ doses. By contrast, the normal individuals studied exhibited marked changes in the peripheral parameters under the influence of thyroid hormone. Thus, normal and RTH subjects were well separated by both central and peripheral responses to T₃.

C23’s TSH was not suppressed at the high T₃ dose, evidence of more profound central resistance even than that noted in most of the historical RTH cohort. However, in our evaluation of C23, we showed that multiple peripheral tissues exhibited a normal response to T₃ despite this central resistance. Normally these peripheral parameters demonstrated a sensitivity to rising T₃ levels, whereas RTH individuals lacked responses to T₃. Here is where C23 diverged importantly from the previously reported RTH patients. Her peripheral markers mirrored those of normal subjects, and despite the fact that C23 shared central resistance with GRTH patients, her peripheral sensitivity to T₃ was normal.

C23 demonstrated clear hepatic, musculoskeletal, and neuropsychological sensitivity to T₃. It is worth noting, though, that although these peripheral tissues were sensitive to changes in T₃, the degree of sensitivity varied among tissues. It remains to be seen if other CRTH patients display a similar variability in peripheral sensitivity to thyroid hormone. Based on the literature, we suggest that different CRTH patients may have different degrees of peripheral thyroid hormone sensitivity. Whether the explanation for these differences can be attributable to TR mutation alone will require a better understanding of the molecular mechanisms underlying CRTH.

The cardiac evaluation raises more questions than it answers. Resting tachycardia is considered by some to be a hallmark of RTH (4). Others attempt to use heart rate to separate GRTH and CRTH (9, 37). Like the majority of subjects reported by Brucker-Davis et al. (13), we found our subject’s resting heart rate to be normal. Further, the rise of C23’s heart rate while taking T₃ was less than that seen in either normal or GRTH patients in the literature. Similarly, the more sophisticated echocardiographic evaluation failed to detect T₃ sensitivity in either C23 or a normal individual. It is clear that heart rate alone is both a poor indicator of RTH status and insufficient to separate individuals into GRTH and CRTH categories.

The nature of our study precluded evaluation of more chronic thyroid hormone-mediated changes. It is possible that some cardiac sequelae of hyperthyroid states represent chronic exposure. In addition, studies in transgenic mice have implicated TR- in cardiac phenomena (20). Tissue-specific expression of TR isoforms, therefore, is likely to play a part mediating RTH in different tissues. The interplay among the TR isoforms in this subject remains an active topic of research.

Although the neuropsychological testing demonstrated T₃ sensitivity in an individual with central thyroid hormone resistance, the nature of that sensitivity was surprising. Although the normal subject experienced improvement on some tests and deterioration on others, C23 demonstrated improvement in all areas evaluated. Additional subjects will need to be studied to ascertain whether the changes measured in C23 should be interpreted simply as T₃ sensitivity or whether those changes reflect an aspect of central resistance that was overcome.

TRH-stimulated PRL levels have been reported to separate RTH individuals from normal subjects (21). Sarne et al. reported that TRH-stimulated PRL levels during T₃ suppression testing made a clear distinction. Normal individuals suppressed their TRH-stimulated PRL levels to 50% and 25% of their baseline TRH-stimulated PRL levels on medium and high T₃ doses, respectively. RTH individuals had no suppression of TRH-stimulated PRL on those T₃ doses. In contrast, Snyder et al. found no change in TRH-stimulated PRL levels when normal individuals took 30 µg T₃ and 120 µg T₄ daily for 3–4 weeks (31). Our data contradict those of both groups, in that C23, our normal subject, and our GRTH subject all saw similar suppression of their TRH-stimulated PRL levels on the low, medium, and high T₃ doses. It is likely that the variability in suppression of TRH-stimulated PRL is such that it cannot serve as a reliable indicator of resistance status.

It is interesting to note that both the index case and her affected sister had high circulating TSH levels, with free thyroid hormone levels only in the high normal range. Although C23 underwent radioactive iodine ablation therapy, the sister did not. However, the sister did have a significant antithyroperoxidase antibody titer, suggesting the possibility of coexistent Hashimoto’s disease. It seems unlikely that the proband is hypothyroid, in that her symptoms are those of euthyroidism or hyperthyroidism. Importantly, C23’s PRL level was normal and exhibited a normal, not a hypothyroid, response to TRH stimulation. If the sister were to become frankly hypothyroid, failure to diagnose her CRTH would result in overtreatment with thyroid hormone. Conversely, the elevated TSH levels may reflect the secretion of relatively bioinactive TSH in this kindred. For example, if pituitary resistance with the R383H mutation were greater than hypothalamic resistance, more TSH would be released, but it would lack the TRH-mediated posttranslational processing required for maximal potency. Biochemical parameters in this instance would be consistent with those that we observed in our kindred.

Another aspect of this study is that it represents the first of our CRTH patients with documentation of affected family members. GRTH mutations are usually found in families. Although some researchers suggest that spontaneous CRTH mutations are more common (4), others have found that familial CRTH is as common as familial GRTH (9, 38). We have not been able to document familial involvement with our R429Q mutation (22), but both R338L mutation reports (39, 40) and the other R383H report (19) include affected family members.

In separating CRTH from GRTH, it is important to note the paucity of both baseline and T₃ suppression data of thyroid hormone-responsive gene products. The literature includes references to both selectively CRTH individuals and GRTH individuals. The CRTH patients are diagnosed with subjective symptoms of thyrotoxicosis and elevated heart rates. Only the R338L mutation (39), the R338W mutation (41), and our previously reported R429Q mutation (22) are presented with T₃ suppression data to confirm the CRTH diagnosis. The result of the failure to more thoroughly evaluate RTH patients is significant, because misassignment of these individuals based on the lack of clinical data is possible. C23 might easily have been assigned the GRTH diagnosis in the absence of the T₃ suppression protocol. Although C23 complained of palpitations intermittently before her diagnosis, there was little else in her subjective history to indicate CRTH. Although the palpitation complaint in conjunction with elevated thyroid hormone levels has been interpreted as a sign of thyrotoxicosis, increased heart rates have also been observed in GRTH individuals (13). She was not tachycardic, and even her high normal heart rate was most consistent with deconditioning from a sedentary life style.

Delineation of CRTH from GRTH is important for two reasons. Clinically, treatment of the two conditions is quite different. Although those subjects with GRTH should receive either thyroid hormone or no treatment, those with CRTH require treatment to alleviate their thyrotoxic symptoms. Failure to correctly diagnose these patients frequently leads to radioactive thyroid ablation for presumed Graves’ disease. Although this may be helpful in patients with CRTH, it is clearly the wrong therapy for patients with GRTH.

In addition, efforts to associate molecular mechanism and phenotype require reliable phenotypic definitions. To date, two molecular mechanisms responsible for the CRTH and GRTH disorders have been offered. Using the R338L, R338W, and R429Q mutations, we found an important difference between the ß1 and ß2 isoforms of the TR (18). Although the above CRTH mutations had weak dominant negative activities in the ß1 isoform, in the ß2 isoform their dominant negative activities were high. This contrasted with the GRTH mutations tested, in which dominant negative activities were high for both isoforms. The isoform difference proved interesting, in that the ß1 isoform is found throughout the body, whereas the ß2 isoform is found primarily in the pituitary and hypothalamus. Clifton-Bligh et al. (19) used the R383H mutation to demonstrate its strong dominant negative activity on TSH and TRH promoters in contrast to its weak dominant negative activity on peripheral gene promoters. They concluded that the mutation, not the TR isoform, mediated the CRTH disorder. It is possible, however, that more than one mechanism can result in CRTH.

The drive to further associate molecular and clinical phenomena in RTH is hampered by insufficient clinical evaluation of the affected individuals. In vitro characterizations of various mutations cannot be secure without clear assignment of the clinical phenotypes. To address this issue, thorough clinical evaluation of RTH subjects will need to accompany the identification of their mutations. Then, a basis for clinical/molecular associations will be established. In this report, R383H becomes one of a small number of rigorously classified CRTH mutations. As such, its in vitro analysis will prove important in providing a molecular explanation for the difference in RTH phenotypes.

	Acknowledgments

 
The technique to measure Achilles tendon reflex relaxation times was designed and implemented by Cécile Smeesters and Mary K. Hannan of the Orthopedic Biomechanics Laboratory at Beth Israel Deaconess Medical Center.

	Footnotes

 
¹ This work was supported by NIH Grants DK-02423 (to J.D.S.), DK-43653 and DK-49126 (to F.E.W.), and RR-01032 (to the Beth Israel Deaconess Medical Center General Clinical Research Center).

Received March 16, 1999.

Revised May 4, 1999.

Accepted June 1, 1999.

	References

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