A 19-YEAR STORY OF ADRENAL HEMORRHAGE, ADRENAL INSUFFICIENCY, AND ADRENAL RECOVERY: DYNAMIC COSYNTROPIN RESULTS WITH TREATMENT CONSIDERATIONS.

There is limited information on the long-term natural history of adrenal function in adrenal hemorrhage following sepsis. The 19-year history of a patient is described who suffered adrenal hemorrhage during pneumococcal sepsis. Adrenal reserve using Cosyntropin testing with the 250 mcg dose was evaluated at seven time points during this interval, and a close observation of the patient enabled clinical correlation with adrenal status. The cosyntropin testing showed a 60 minute cortisol level post-hemorrhage of: 303.4 nmol/L (11.0 mcg/dL), one month; 656.6 nmol/L (23.8 mcg/dL), 1 year 10 months; and 714.5 nmol/L (25.9 mcg/dL), 19 years. Over the years the patient experienced hypoadrenal symptoms requiring both hydrocortisone and fludrocortisone until her adrenal function consistently demonstrated a 60 minute cortisol level of ~ 717.3 nmol/L (26 mcg/dL). Adrenal calcifications were visualized by ultrasound imaging and ultimately resolved. In conclusion, the patient's hypothalamic-pituitary-adrenal system appeared to have ultimately restored normal basal adrenal function 19 years after the initial hemorrhage, and the dynamic cosyntropin data indicate that normal adrenal function should not be assumed with a 60 minute cortisol level of 496.6 - 551.8 nmol/L (18 - 20 mcg/dL). Finally, mineralocorticoid as well as glucocorticoid may be important for improved mental acuity in primary hypoadrenalism.

Altered cardiac phenotype in transgenic mice carrying the delta337 threonine thyroid hormone receptor beta mutant derived from the S family.

The heart has been recognized as a major target of thyroid hormone action. Our study investigates both the regulation of cardiac-specific genes and contractile behavior of the heart in the presence of a mutant thyroid hormone receptor beta1 (T3Rbeta1-delta337T) derived from the S kindred. The mutant receptor was originally identified in a patient with generalized resistance to thyroid hormone. Cardiac expression of the mutant receptor was achieved by a transgenic approach in mice. As the genes for myosin heavy chains (MHC alpha and MHC beta) and the cardiac sarcoplasmic reticulum Ca2+ adenosine triphosphatase (SERCA2) are known to be regulated by T3, their cardiac expression was analyzed. The messenger RNA levels for MHC alpha and SERCA2 were markedly down-regulated, MHC beta messenger RNA was up-regulated. Although T3 levels were normal in these animals, this pattern of cardiac gene expression mimics a hypothyroid phenotype. Cardiac muscle contraction was significantly prolonged in papillary muscles from transgenic mice. The electrocardiogram of transgenic mice showed a substantial prolongation of the QRS interval. Changes in cardiac gene expression, cardiac muscle contractility, and electrocardiogram are compatible with a hypothyroid cardiac phenotype despite normal T3 levels, indicating a dominant negative effect of the T3Rbeta mutant.

Prothrombin Greenville, Arg517-->Gln, identified in an individual heterozygous for dysprothrombinemia.

A 64-year-old white male was referred for evaluation of prolonged prothrombin time (PT) and activated partial thromboplastin time (aPTT) obtained before elective surgery with initial PT and PTT results of 14.9 and 38.4 seconds, respectively, which corrected to normal in 1:1 mixes with normal plasma. Functional prothrombin assay indicated a level of 51% with thromboplastin as an activator. The prothrombin antigen was 102%. This discordance in the functional and immunologic prothrombin levels was evidence for dysprothrombinemia. Western blotting showed that thrombin was formed at a normal rate in diluted plasma consistent with a mutation within the thrombin portion of prothrombin. DNA was isolated from leukocytes and the thrombin exons were amplified by polymerase chain reaction, cloned, and sequenced. For exon 13, eight clones were sequenced with four clones showing a point mutation in the codon for Arg517, which would result in substitution by Gln. Arg517 is part of the Arg-Gly-Asp(RGD) sequence in thrombin and contributes to an ion cluster with aspartic acid residues 552 and 554. Mutation at this residue most probably distorts the structure of the Na+ binding site in thrombin. This is the first report indicating the critical role of Arg517 in the normal physiological interaction of thrombin with fibrinogen. This dysprothrombin is designated Prothrombin Greenville.

The cystic fibrosis transmembrane regulator gene is expressed in the human endocervix throughout the menstrual cycle.

OBJECTIVE: To measure cystic fibrosis transmembrane regulator (CFTR) gene expression in cervical secretions during the menstrual cycle. DESIGN: Prospective, descriptive clinical study. PATIENTS: Thirteen healthy women with ovulatory menstrual cycles. INTERVENTIONS: Endocervical cells and secretions were obtained by cytobrushings during the midfollicular, midcycle, and luteal phases. The cells were analyzed by reverse transcriptase-polymerase chain reaction (RT-PCR) for CFTR and glyceraldehyde 3-phosphate dehydrogenase (GAPDH) gene expression. MAIN OUTCOME MEASURES: Detection of CFTR gene expression and a quantitative comparison of the levels of CFTR to GAPDH gene expression. RESULTS: All endocervical samples exhibited some degree of CFTR gene expression throughout the menstrual cycle; however, the levels of expression were variable. Cystic fibrosis transmembrane regulator gene expression did not correlate with E2 or P levels. CONCLUSION: The production of copious cervical secretions at the time of ovulation in part may be because of the transport of sodium and water across endocervical cell membranes as a result of E2-stimulated CFTR mRNA and protein. Although cervical mucus becomes thick and scant during the luteal phase, CFTR gene expression is present in these secretions.

Characterization of a low affinity thyroid hormone receptor binding site within the rat GLUT4 gene promoter.

Previous studies have demonstrated that thyroid hormone (T3) stimulates insulin-responsive glucose transporter (GLUT4) transcription and protein expression in rat skeletal muscle. The aim of the present study was to define a putative thyroid hormone response element (TRE) within the rat GLUT4 promoter and thus perhaps determine whether T3 acts directly to augment skeletal muscle GLUT4 transcription. To this end, electrophoretic mobility shift analyses were performed to analyze thyroid hormone receptor (TR) binding to a previously characterized 281-bp T3-responsive region of the rat GLUT4 promoter. Indeed, within this region, a TR-binding site of the standard DR + 4 TRE variety was located between bases -457/ -426 and was shown to posses a specific affinity for in vitro translated TRs. Interestingly, however, the GLUT4 TR-binding site demonstrated a significantly lower affinity compared to a consensus DR + 4 TRE, and only bound TRs appreciatively in the form of high affinity heterodimers, in this case with the cis-retinoic acid receptor. In conclusion, these data demonstrated the presence of a specific TR-binding site within a T3-responsive region of the rat GLUT4 promoter and thus support the supposition that thyroid hormone acts directly to stimulate GLUT4 transcription in rat skeletal muscle. Moreover, characterization of a novel TR-binding site with low affinity suggests an additional mechanism by which the intrinsic activity and responsiveness of thyroid hormone regulated genes may be modulated.

Enhanced levels of wild-type versus mutant thyroid hormone receptor beta 1 messenger RNA in fibroblasts from heterozygotes of kindred S with thyroid hormone resistance.

Thyroid hormone resistance syndromes, which result from heterozygous mutations in the beta 1 thyroid hormone receptor gene, are sometimes associated with adult short stature, but more frequently with delayed bone age (BA). Primary fibroblasts from young children with both delayed BA and short stature from a kindred A have been reported to overexpress the mutant allele. However, in fibroblasts from affected members of two different kindreds with thyroid hormone resistance, S and Mf, there were equal levels of mutant and wild-type beta 1 mRNA. We investigated the ontogeny of differential allelic expression using competitive reverse transcription with PCR (RT-PCR) to measure relative mRNA levels for beta 1 and S receptor in very young affected children of kindred S. Total RNA was prepared from fibroblasts of two patients (ages 3-0.5/12 and 1-4/12 years) with delayed BA but normal growth curves. Using PCR amplimers that create an Mlu-1 site in wild-type but not mutant cDNA products from the competitive RT, we quantitated mRNA levels. Normal beta 1 mRNA was present at nearly twice the level of the mutant mRNA in cells from these patients. Relative expression of the c-erbA beta alleles thus appeared to be increased during this period of somatic growth. The relative overexpression of the normal allele potentially counteracted the potent dominant negative effect of the S receptor during early childhood ameliorating a deleterious effect on linear growth.

Differential expression of ob mRNA in rat adipose tissues in response to insulin.

The recently cloned obese (ob) gene encodes a fat-specific mRNA and a protein which is believed to regulate satiety and metabolic rate so as to control fat storage. In the present study we investigated rat ob mRNA levels in different fat depots and the effects of insulin infusion on ob mRNA expression. Northern blot analysis showed the abdominal fat (epididymal and perirenal fat pads) had higher ob mRNA levels than subcutaneous fat. After a 2.5-hr infusion of insulin into fasted rats, ob mRNA levels were increased by 3.0 and 1.9-fold in epididymal and perirenal fat pads, respectively. However, no change of ob mRNA level was observed in the subcutaneous fat depot. These data demonstrate adipose depot site-specific expression of ob mRNA and support the hypothesis that insulin plays an important role in the expression of ob mRNA.

A novel C-terminal domain in the thyroid hormone receptor selectively mediates thyroid hormone inhibition.

Resistance to thyroid hormone (RTH) action is due to mutations in the beta-isoform of the thyroid hormone receptor (TR-beta). RTH patients display inappropriate central secretion of thyrotropin-releasing hormone (TRH) from the hypothalamus and thyrotropin (TSH) from the anterior pituitary in association with abnormal peripheral tissue responses to thyroid hormone. Whether TR-beta mutations cause a selective form of RTH, which only leads to abnormal pituitary TSH secretion (PRTH), is unclear. In a patient with PRTH, a novel mutation of a conserved arginine residue adjacent to the ninth heptad of TR-beta selectively disrupts TR homodimer formation. The mutant TR displays normal or enhanced function on stimulatory thyroid hormone response elements found in peripheral tissues, but has defective function on inhibitory thyroid hormone response elements found in the TRH and TSH subunit genes and explains the PRTH phenotype. This is the first report of a mutation in a member of the nuclear receptor superfamily that selectively abolishes hormone-dependent inhibition and localizes a novel C-terminal domain necessary for this property.

High dose intravenous, but not low dose subcutaneous, insulin-like growth factor-I therapy induces sustained insulin sensitivity in severely resistant type I diabetes mellitus.

We have previously demonstrated weekly iv insulin-like growth factor-I (IGF-I; 500 micrograms/kg) bolus therapy to be effective in inducing sustained insulin sensitivity in a patient with type I diabetes mellitus and massive insulin resistance. The present study was undertaken to determine the efficacy of daily sc IGF-I in the treatment of two severely insulin-resistant type I diabetic patients (requiring in excess of 3500 U insulin/day) compared to weekly iv IGF-I therapy. Prolonged insulin sensitivity was achieved in both patients after weekly 500 micrograms/kg iv bolus infusions of IGF-I, with sc insulin requirements falling to approximately 1 U/kg.day. Smaller iv doses (250 micrograms/kg) of IGF-I were ineffective in acutely lowering serum glucose or inducing sustained insulin sensitivity. However, even this smaller IGF-I dose resulted in acute symptomatic hypophosphatemia, which could be prevented by coadministration of potassium phosphate. With sc administered IGF-I (up to 10 mg twice daily), insulin appeared to control patient glucose concentrations, but severe insulin resistance returned within 72 h of discontinuing IGF-I therapy. IGF-I dosing was decreased to the lowest concentration that maintained euglycemia (7.5 mg in the morning and 2.5 mg in the evening). However, severe arthropathy in both patients and neurological symptoms including multiple cranial nerve palsies in one patient were associated with chronic therapy. We conclude that both iv and sc administered IGF-I can precipitate acute symptomatic hypophosphatemia. Chronic low dose sc therapy may be associated with severe neuropathy and arthropathy, and does not induce the sustained insulin sensitivity associated with high dose intermittent bolus IGF-I therapy.

Resistance to thyroid hormone in children.

The genetic etiology of thyroid hormone resistance syndromes is now well established. Two clinical variants, generalized resistance to thyroid hormone (GRTH) and selective pituitary resistance to thyroid hormone (PRTH), are, in most cases, caused by heterozygous mutations in the ligand-binding domain of the c-erbA beta thyroid hormone receptor gene. No human mutations have yet been described in the other related receptor gene, c-erbA alpha. In resistant patients, the mutant beta receptors act as dominant negative proteins and inhibit function of the normal beta receptor (expressed from one allele) and the normal alpha receptor (expressed from two alleles). Patients homozygous for a dominant negative allele (the Bercu patient) and without any beta receptor (the Refetoff patient) have been described. Patients with GRTH and PRTH both present with elevated free thyroxine and triiodothyronine and inappropriately normal thyroid-stimulating hormone, but the former patients are clinically euthyroid, whereas the latter patients have symptoms and signs of hyperthyroidism. However, in some cases, different patients who have been classified as having GRTH and PRTH have been found to have identical beta mutations. A recent study of the level of pituitary resistance in a large kindred with GRTH (ARG-320-HIS mutation) indicated a contributory gene in the regulation of thyroid hormone action. Relative overexpression of the mutant PRO-453-HIS receptor at the level of messenger RNA in patient fibroblasts (kindred A) was associated with short stature. Finally, an ARG-316-HIS mutation (kindred G-H) was associated with relatively weak dominant negative activity and perturbed DNA-binding properties.(ABSTRACT TRUNCATED AT 250 WORDS)

Divergent dimerization properties of mutant beta 1 thyroid hormone receptors are associated with different dominant negative activities.

Syndromes of resistance to thyroid hormones are caused by mutations in the T3-binding domain of the c-erbA beta thyroid hormone receptor gene. The S receptor (deletion of THR332) is a potent dominant negative protein cloned from a kindred with generalized resistance to thyroid hormones. The G-H receptor (ARG311HIS) has compromised dominant negative function and was found in both normal individuals and in a patient with severe pituitary resistance to thyroid hormones. We have investigated the mechanism responsible for the difference in receptor phenotypes by analyzing the binding of S and G-H receptors to thyroid hormone response elements with electrophoretic mobility shift analysis. Wild-type human c-erbA beta 1 (WT), S, and G-H receptors were synthesized in reticulocyte lysate, reacted with a thyroid hormone response element consisting of a direct repeat with 4 base pairs (DR+4; AGGTCA CAGG AGGTCA), and the products analyzed by gel shift. G-H receptor homodimerization was greatly impaired; G-H formed predominantly monomeric complex compared with monomeric and homodimeric WT complexes. The G-H receptor was able to form heterodimeric complexes with cellular thyroid hormone receptor auxiliary protein (TRAP) factors including the human retinoid X receptor-alpha. When TRAP was limiting, the levels of G-H heterodimeric complex were 2- to 3-fold reduced compared with WT receptor. In contrast to the WT and G-H receptors, the S receptor formed almost exclusively homodimeric complex with DR+4; the approximate ratio of S:WT:G-H homodimeric complexes at equivalent concentrations of receptors was 60:20:1. A measurable increase (1.2- to 2.6-fold) in heterodimeric complex formation was observed with the S receptor relative to WT when TRAP was at limiting concentration. As reported previously by others, thyroid hormone significantly reduced the WT homodimeric complex with DR+4. There was no effect on the S homodimeric complex. Finally, the WT, S, and G-H receptors formed different complexes with the element consisting of an inverted repeat with 5 base pairs (IR+5; AGGTCA ACAGT TGACCT) and the IR element (AGGTCA TGACCT), which were differently regulated by thyroid hormone. The S receptor bound as a homodimer with IR+5, whereas the WT receptor bound as a homodimer only with thyroid hormone. No homodimeric complex formed with IR+5 and the G-H receptor. Qualitatively similar results were observed with the IR element. We conclude that the ARG311HIS mutation severely perturbs the homodimerization and, to a much less degree, heterodimerization functions of the c-erbA beta 1 receptor. Furthermore, the THR332 deletion mutation augments homodimerization of the c-erbA beta 1 receptor. These results indicate that different mutations in the c-erbA beta 1 thyroid hormone receptor have divergently affected dimerization activities which seem to influence the level of dominant negative activity in man.

Effects of chronic phorbol ester treatment on protein kinase C activity, content, and gene expression in the human monoblastoid U937 cell.

Immediate and sustained signal transduction is involved in mediating phorbol ester-induced changes in growth and differentiation. Activation of protein kinase C (PKC) is the initial step in phorbol ester-induced signal transduction. By virtue of preferential down-regulation of individual isoforms and generation of proteolytically derived kinase activities, the signal transduced by sustained activation of this pathway may differ substantially from that generated initially upon application of the phorbol ester. To examine the effect of chronic phorbol ester-induced activation of this pathway, the relationship between PKC activity/content and AP-1 binding activity and gene expression was studied in the U937 cell. Phorbol ester-induced differentiation of the U937 cell into a monocyte/macrophage-like cell requires sustained activation of the PKC pathway. AP-1 binding activity was enhanced by 12-O-tetradecanoylphorbol-13-acetate (TPA) and in a temporally dependent manner, with conversion of a high to low mobility band shift occurring after a 12-h exposure to TPA. After a 72-h exposure, AP-1 binding activity was maximally increased by 1 nM TPA and remained elevated to a similar degree even after treatment with 600 nM TPA. Enhanced AP-1 binding activity was dependent upon continuous exposure to TPA and was not secondary to differentiation. A 72-h treatment with one nM TPA maximally increased expression of c-jun, krox-24, and jun-B mRNA transcripts. Exposure to higher TPA concentrations decreased the content of these transcripts. Maximal expression of collagenase and plasminogen activator receptor transcripts required exposure to much higher TPA concentrations (100 nM).(ABSTRACT TRUNCATED AT 250 WORDS)

Competitive polymerase chain reaction quantitation of c-erbA beta 1, c-erbA alpha 1, and c-erbA alpha 2 messenger ribonucleic acid levels in normal, heterozygous, and homozygous fibroblasts of kindred S with thyroid hormone resistance.

Mutations in the T3-binding domain of the thyroid hormone receptor gene c-erbA beta result in dominant negative proteins and thyroid hormone resistance syndromes. Variable clinical manifestations of resistance to thyroid hormones have been reported, including short stature and neuropsychological abnormalities. The molecular bases for heterogeneity of phenotype among and within kindreds have not been fully elucidated. Recent investigations have considered differential expression of mutant and wild-type beta 1-receptor alleles and the regulation thereof as a mechanism to explain differential sensitivity to thyroid hormones. We used reverse transcription-competitive polymerase chain reaction (PCR) to measure c-erbA beta 1, c-erbA alpha 1, and c-erbA alpha 2 mRNAs in skin fibroblasts cultured from normal subjects, heterozygotes, and a severely affected homozygous mutant of kindred S. The homozygous mutant of kindred S had severe growth and mental retardation. After reverse transcription with primers specific for each of the c-erbA mRNAs, first strand cDNAs were amplified by PCR using subtype-specific amplimers. Primer design allowed simultaneous detection of wild-type and mutant messages in heterozygous fibroblasts and showed an approximately 1:1 ratio of these mRNAs in three patients. Inclusion of competitive standard cDNAs of known concentration in the PCR reactions allowed quantitation of the absolute levels of the beta 1-, alpha 1-, and alpha 2 mRNAs by comparison of products on ethidium bromide-stained agarose gels. These studies showed no effect of the presence of the mutant beta 1-allele, as fibroblast RNA from normal subjects, heterozygotes, and the homozygote gave values of 56-184, 2.8-12, and 23-40 attomol/5 micrograms total RNA for beta 1-, alpha 1-, and alpha 2 mRNAs, respectively. We conclude that these sensitive methods allow the detection of molecular species present at levels as low as 10 molecules/cell, and that this potent dominant negative receptor does not disrupt c-erbA expression at the level of mRNA. The neuropsychological sequelae of the kindred S mutation are not due to relative overexpression of the mutant allele.