Germline mutations in the thyrotropin receptor gene cause non-autoimmune autosomal dominant hyperthyroidism.

The thyrotropin receptor (TSHR), a member of the large family of G protein-coupled receptors, controls both the function and growth of thyroid cells via stimulation of adenylyl cyclase. We report two different mutations in the TSHR gene of affected members of two large pedigrees with non-autoimmune autosomal dominant hyperthyroidism (toxic thyroid hyperplasia), that involve residues in the third (Val509Ala) and seventh (Cys672Tyr) transmembrane segments. When expressed by transfection in COS-7 cells, the mutated receptors display a higher constitutive activation of adenylyl cyclase than wild type. This new disease entity is the germline counterpart of hyperfunctioning thyroid adenomas, in which different somatic mutations with similar functional characteristics have been demonstrated.

Familial congenital hypothyroidism due to inactivating mutation of the thyrotropin receptor causing profound hypoplasia of the thyroid gland.

Thyroid gland agenesis is the most common cause of congenital hypothyroidism and is usually sporadic. We investigated a brother and sister from consanguineous parents, ascertained through systematic newborn screening, and initially diagnosed with thyroid agenesis. Careful cervical ultrasonography in both patients revealed a very hypoplastic thyroid gland. By direct sequencing of the thyrotropin receptor gene, we identified the substitution of threonine in place of a highly conserved alanine at position 553, in the fourth predicted transmembrane domain. The mutation was found homozygous in the affected siblings, and heterozygous in both parents and two unaffected siblings. Functional analysis in transfected COS-7 cells showed that it resulted in extremely low expression at the cell surface as compared with the wild-type receptor, in spite of an apparently normal intracellular synthesis. The small amount of mutated receptor expressed at the surface of transfected cells bound thyrotropin with normal affinity and responded in terms of cAMP production, but the in vivo significance of these data from overexpressed receptor in transfected cells is unclear. Of note, blood thyroglobulin was unexpectedly elevated in the patients at the time of diagnosis, a finding that might prove useful in refining etiologies of congenital hypothyroidism.

Isodisomy of chromosome 6 in a newborn with methylmalonic acidemia and agenesis of pancreatic beta cells causing diabetes mellitus.

Isodisomy (ID) is a genetic anomaly defined as the inheritance of two copies of the same genetic material from one parent. ID in an offspring is a rare cause of recessive genetic diseases via inheritance of two copies of a mutated gene from one carrier parent. We studied a newborn female with a mut(o) of methylmalonic acidemia and complete absence of insulin-producing beta cells in otherwise normal-appearing pancreatic islets, causing insulin-dependent diabetes mellitus. The patient died 2 wk after birth. Serotyping of the HLA antigens, DNA typing of HLA-B and HLA class II loci, study of polymorphic DNA markers of chromosome 6, and cytogenetic analysis demonstrated paternal ID, involving at least a 25-centiMorgan portion of the chromosome pair that encompasses the MHC. ID probably caused methylmalonic acidemia by duplication of a mutated allele of the corresponding gene on the chromosome 6 inherited from the father. It is also very likely that ID was etiologically related to the agenesis of beta cells and consequent insulin-dependent diabetes mellitus in our patient. We thus speculate on the existence of a gene on chromosome 6 involved in beta cell differentiation.

TSH Receptor Mutations and Thyroid Disease.

Mutations of the thyrotropin receptor (TSHr) can be loss of function or gain of function. Loss-of-function mutations can affect a variety of loci in the TSHr gene. Their most common manifestation is resistance to TSH; they may also be the cause of a subset of cases of congenital hypothyroidism. Gain-of-function mutations are of greater theoretical interest. Somatic mutations constitutively activating the TSHr are the major cause of benign toxic thyroid adenomas, and of some cases of multinodular goiters. They underlie hereditary toxic thyroid hyperplasia, and have been found in cases of sporadic congenital non-autoimmune hyperthyroidism. A role for TSHr polymorphisms in Graves' disease has not been documented.

Evidences for an allelic variant of the human LC/CG receptor rather than a gene duplication: functional comparison of wild-type and variant receptors.

Two different human LH receptor sequences have been published, differing by a six-base pair insertion encoding Leu-Gln at position 55-60. It has recently been proposed that this would reflect the existence of two LH receptor loci in the human genome. The present results demonstrate that both sequences exist as allelic variants in the Caucasian population. Allelic frequency of"LQ variant" and "wild-type" (alphaLQ) allele are 0.26 and 0.74 respectively. In contrast, the LQ allele is virtually absent from the Japanese population. Functional characterization of both alleles by transient expression in COS-7 cells did not reveal any difference between the two receptors, neither for cell surface expression nor for cAMP production and sensitivity to hCG/LH.

Failure of membrane targeting causes the functional defect of two mutant sodium iodide symporters.

Molecular cloning of the sodium/iodide symporter (NIS) allowed identification of NIS gene mutations in patients with iodide trapping defect. Whereas various mutant human (h) NIS molecules display loss of function when expressed by transfection in mammalian cells, the precise mechanism(s) responsible for the functional abnormality of these proteins remains unknown. With the aim to explore these mechanisms in three natural hNIS mutants identified previously in patients with iodide trapping defect (Q267E, S515X, and C272X), we have prepared tools allowing direct measurement of the protein at its normal location in the plasma membrane. A COS-7 cell line was made by transfection that stably expressed high levels of wild-type hNIS. It was used to screen by flow cytometry monoclonal antibodies (mAbs) prepared from mice immunized against hNIS. Genetic immunization was performed by im injection of a wild-type hNIS complementary DNA construct, because this procedure has demonstrated the ability to produce antibodies recognizing native membrane proteins. One mAb that recognized an epitope of hNIS exposed on the extracellular side of the plasma membrane was selected for further studies. The epitope was localized on the sixth putative extracellular loop of the protein on the basis that the mAb did not recognize rat NIS, which exhibits major sequence differences in this segment. When this mAb was used to test by flow cytometry the expression of the three mutant hNIS proteins in transfected COS-7 cells, it detected similar amounts of wild-type, Q267E, and the S515X hNIS molecules in permeabilized cells. In contrast, only the wild-type hNIS was detected at the surface of nonpermeabilized cells. The C272X hNIS truncation mutant was not detected in intact or permeabilized cells. This is consistent with the absence of the mAb epitope from this mutant, which is expected to lack the sixth extracellular loop. Our data demonstrate that faulty membrane targeting is implicated in the mechanisms causing iodide trapping defect in the Q267E and S515X natural hNIS mutants.

Diversity and prevalence of somatic mutations in the thyrotropin receptor and Gs alpha genes as a cause of toxic thyroid adenomas.

A total of 33 different autonomous hot nodules from 31 patients, originating mainly from Belgium, were investigated for the presence of somatic mutations in the TSH receptor and Gs alpha genes. This constitutes an extension of our previous study, including the first 11 nodules of the series. The complete coding sequence of the TSH receptor gene and the segments of Gs alpha known to harbor mutations impairing guanosinetriphosphotase activity were studied by direct sequencing of genomic DNA extracted from the nodules. DNA from the juxtanodular tissue or peripheral white blood cells was analyzed in all patients to confirm that the mutations identified were somatic. Twenty-seven mutations (82%) were found in the TSH receptor gene, affecting a total of 12 different residues or locations. All these mutations but 2 (see below) have been identified previously as activating mutations. Only 2 mutations were found in Gs alpha (6%). In 4 nodules, no mutation was detected. Five residues (Ser281, Ile486, Ile568, Phe631, and Asp633) were found mutated in 3 or 4 different nodules, making them hot spots for activating mutations. Phe631 and Asp633 belong to a cluster of 5 consecutive residues (629-633) in the N-terminal half of transmembrane segment VI; which harbor together 44% of the mutations identified in this cohort. Two novel mutations were identified: a point mutation causing substitution of Phe for Leu at position 629 (L629F); and a deletion of 12 bases removing residues 658-661 at the C-terminal portion of exoloop 3 (del658-661). When tested by transfection in COS-7 cells, both mutant receptors display increase in constitutive stimulation of basal cAMP accumulation. Although it is still capable of binding TSH, the del658-661 mutant has completely lost the ability to respond to the stimulation by the hormone. Our results demonstrate that, in a cohort of patients from a moderately iodine deficient area, somatic mutations increasing the constitutive activity of the TSH receptor are the major cause of autonomous hot nodules.

Autosomal dominant transmission of congenital thyroid hypoplasia due to loss-of-function mutation of PAX8.

Congenital hypothyroidism (CH) is a relatively frequent and potentially severe disease. It is classically subdivided into: 1) thyroid dysgenesis (TD), a defect in the organogenesis of the gland leading to hypoplastic, ectopic, or absent thyroid gland; or 2) thyroid dyshormonogenesis, a defect in one of the biochemical mechanisms responsible for thyroid hormone synthesis. Most cases of TD are sporadic, although familial occurrences have occasionally been described. Recently, several genes have been implicated in a small proportion of TD, but, in the majority of the cases, the etiology remains unknown. PAX8 is a transcription factor involved in thyroid development. So far, three loss-of-function mutations of PAX8 have been described, two in sporadic cases and one in familial thyroid hypoplasia. Here, we describe a novel mutation of PAX8 causing autosomal dominant transmission of CH with thyroid hypoplasia. The mutation consists of the substitution of a tyrosine for cysteine 57 in the paired domain of PAX8. When tested in cotransfection experiments with a thyroid peroxidasse promoter construct, the mutant allele was unable to exert its normal transactivation effect on transcription. Our results give further evidence that, contrary to the situation in knockout mice, haplo-insufficiency of PAX8 is a cause of CH in humans.

Constitutive activation of the TSH receptor by spontaneous mutations affecting the N-terminal extracellular domain.

Activating mutations of the TSH receptor gene have been found in toxic adenomas and hereditary toxic thyroid hyperplasia. Up to now, all mutations have been located in the serpentine portion of the receptor. We now describe two additional mutations affecting Ser-281 (Ser-281-Thr and Ser-281-Asn) in the ectodomain of the receptor. After transfection in COS cells, both mutants displayed increased constitutive activity for cAMP generation despite expression at a lower level than the wild type. The mutants were responsive to TSH. The present results are compatible with a model in which the activity of the unliganded receptor is kept at a low level by an inhibitory interaction between the N-terminal domain and the serpentine portion of the receptor.

Constitutively active receptors as a disease-causing mechanism.

Membrane receptors have appeared early in evolution as the means for the unicellular organism to sense its environment. With the emergence of social cellular life in multicellular organisms, membrane receptors have acquired the additional functions of sensing the presence of similar cells (as in the aggregation phenomenon of Dictyostelium discoideum) (Klein et al., 1988) or the presence of the mate (Saccharomyces cerevisiae) (Cross et al., 1988), and to detect endocrine signals emitted by cells in distant tissues. As the latter function is central to homeostasis and regulation of cell growth, the downstream regulatory cascades under receptor control are the subject of intense research with implications in virtually all fields of biomedical science. The impact of the analysis of tyrosine kinase-activated cascades on our understanding of carcinogenesis is but one example of such an advance.

Oncogenic mutations in the thyrotropin receptor of autonomously functioning thyroid nodules in the Japanese population.

OBJECTIVE: Constitutively activating mutations of the thyrotropin receptor (TSHR) have been found in the majority of autonomously functioning thyroid nodules (AFTNs) in European patients. The reported frequency of these mutations varies among reports but amounts to 50-80%. To date, only one such mutation responsible for AFTNs has been identified in the Japanese population and the pathogenic role of such mutations in Japanese AFTNs has been questioned. In the present study, we evaluated the frequency of activating mutations in the TSHR and G(alpha)s in 10 Japanese AFTNs. DESIGN: Genomic DNA was extracted from fresh frozen tissue. The TSHR and the almost entire sequence of the gene coding for the alpha subunit of Gs have been amplified and sequenced. RESULTS: In sequence analysis, four mutations in the TSHR (T632A, I486M, M453T and L512R) were found. To complete our analysis, we searched mutations in the gene coding for the alpha subunit of Gs, in the samples negative for TSHR mutations. In one case a mutation (R201H) affecting GTPase activity was found. CONCLUSIONS: If we focus on the solitary nodules, we obtain the same mutation proportion as in European patients (70%). The absence of TSHR and G(alpha)s mutations in a significant proportion of autonomous adenomas in multinodular goiters suggests that other causes may also play a role in the genesis of these lesions.

A familial case of congenital hypothyroidism caused by a homozygous mutation of the thyrotropin receptor gene.

Most of the time congenital hypothyroidism appears as a sporadic disease. In addition to the rare defects in hormonosynthesis associated with goiters, the causes of congenital hypothyroidism include agenesis and ectopy of the thyroid gland. The study of some familial cases has allowed the identification of a few genes responsible for congenital hypothyroidism. We report here a familial case of congenital hypothyroidism, transmitted as a recessive trait, and caused by a homozygous mutation in the thyrotropin receptor (TSH-R). The initial diagnosis of thyroid agenesis, based on the absence of tracer uptake on scintiscan, was incorrect, because ultrasound examination identified severely hypoplastic thyroid tissue in the cervical region.

A novel thyrotropin receptor mutation in an infant with severe thyrotoxicosis.

An infant girl was born at 37 weeks gestation and found to be clinically thyrotoxic at 9 months of age. Thyroid autoantibodies were negative, and thyroid function failed to normalize with medical treatment. The patient underwent a total thyroidectomy. DNA obtained from her thyroid gland and leukocytes was analyzed for thyrotropin receptor (TSHR) mutations using single strand conformation polymorphism and direct sequencing. A mobility shift of polymerase chain reaction (PCR)-amplified DNA was detected on single strand conformation polymorphism gel. Direct sequencing identified a novel point mutation in the fifth transmembrane domain of the TSH receptor at codon 597 (GTC to CTC), resulting in the amino acid substitution of leucine for valine. The mutation was heterozygous and germline, and was not identified in DNA from either of her parents. Expression of the V597L mutant is transiently transfected COS 7 cells displayed increased constitutive cyclic adenosine monophosphate (cAMP) production compared with the wild-type receptor. The mutant is expressed at very low levels on the surface of COS cells, and its response to TSH is marginal.

Congenital central isolated hypothyroidism caused by a homozygous mutation in the TSH-beta subunit gene.

We report a Belgian girl born in 1983 with isolated thyrotropin (TSH) deficiency. Hypothyroidism without goiter was diagnosed at the age of 2 months, with extremely low total thyroxine (T4) at 0.3 microg/dL (4 nmol/L; N[normal]: 5.6-11.4 microg/dL). Basal TSH, only moderately elevated at 14.8 mU/L (N: 0-5.3; competitive radioimmunoassay, RIA), increased to 18.2 mU/L after thyrotropin-releasing hormone (TRH) stimulation, whereas prolactin increased normally. At age 15 years, after withdrawal of levothyroxine (LT4) therapy for 6 weeks, TRH stimulation slightly increased serum TSH using two immunometric assays, from less than 0.03 to 0.07 and from 0.2 to 0.3 (a monoclonal and polyclonal antibody), and from 1.9 to 4.1 mU/L using a polyclonal TSH antibody and iodinated recombinant TSH. Sequencing of the TSH-beta subunit gene revealed a homozygous single nucleotide deletion in codon 105 producing a frame shift that results in a truncated TSH-beta with nonhomologous 9 carboxyterminal amino acids and a loss of the 5 terminal residues. This mutation was previously reported in one Brazilian and two German families. The abnormal, and presumably biologically inactive, TSH can be detected in serum using appropriate antibodies. Its relatively small amount in serum is due to either reduced secretion or rapid degradation. The occurrence of the same mutation in three families of different ethnic origin suggests that this mutation may be prevalent in the population. Common ancestry or de novo mutations in a hot spot cannot be excluded. Finally, we must be aware that neonatal screening of congenital hypothyroidism based on blood spot TSH measurement will not detect this rare but severe genetic defect.

Pathology of the TSH receptor.

Gain of function and loss of function mutations of the TSH receptor have been implicated in the pathogenesis of various thyroid diseases. Gain of function mutations, when somatic, are the first cause of autonomous nodules; when germline, they are responsible for hereditary non-autoimmune toxic thyroid hyperplasia and for some cases of sporadic congenital hyperthyroidism. A subset of mutations modifying the receptor selectivity have recently been found to be involved in the pathogenesis of familial gestational hyperthyroidism. These mutations are of great interest for understanding the mechanism of receptor activation. Loss of function mutations of the TSH receptor are responsible for different phenotypes ranging from asymptomatic resistance to TSH to overt congenital hypothyroidism.

Activating mutations of the TSH receptor gene cause thyroid diseases.

Spontaneous mutations have been identified in the gene encoding the thyrotropin receptor, the effect of which is to activate the receptor in the absence of hormone. When they occur within thyrocytes (somatic mutations) activating mutations cause clonal expansion of the cells into a hyperfunctional thyroid adenoma (toxic nodule). Our results demonstrate that this pathophysiologic mechanism accounts for the majority of toxic adenomas (9 mutations found out of 11 adenomas). The remaining cases are probably secondary to mutations in the G protein Gs. When similar mutations are present in the germ line, they cause a form of non-autoimmune hyperthyroidism transmitted as an autosomal dominant trait. Mutations of the tsh receptor gene have been found in five different families, including that corresponding to the original description of the syndrome by J. Leclère (Nancy). Structure/function studies of the various mutant receptors will contribute to our understanding of the mecanisms involved in the activation of G protein-coupled receptors.

[Medical genetics service]. / Le Service de Génétique Médicale.

Created in 1987, the department of medical genetics finds its origins in molecular endocrinology research which had developed from the seventies at the Institut de Recherche Interdisciplinaire en Biologie Humaine et Moléculaire (IRIBHM) of the Faculty of Medicine. After its fusion with the Center of Human Genetics of the ULB, in 1992, the department is composed of three units: the lab of molecular genetics and oncology, the lab of cytogenetics and a clinical genetics unit. One thousand consultations of genetic counseling and more than 15,000 molecular or cytogenetic diagnostic procedures are performed annually. The development of the clinical activities was paralleled by a very active research activity, resulting in a series of "firsts". Amongst the main results are: the identification of the first mutations responsible for congenital hypothyroidism; the molecular cloning of the TSH receptor and of a series of "orphan" G protein-coupled receptors; the identification of a novel neuropeptide, nociceptin, by the first example of "reverse pharmacology"; the identification of olfactory receptors on the sperm of mammals, including man; the identification in molecular terms of the mechanisms responsible for acquired and hereditary hyperthyroidisms; the identification of the chemokine receptor CCR5 as the major coreceptor of HIV-1, and of the prevalent mutation of CCR5 conferring resistance to HIV to about 1% of the European population.

Necrostatin-1 analogues: critical issues on the specificity, activity and in vivo use in experimental disease models.

Necrostatin-1 (Nec-1) is widely used in disease models to examine the contribution of receptor-interacting protein kinase (RIPK) 1 in cell death and inflammation. We studied three Nec-1 analogs: Nec-1, the active inhibitor of RIPK1, Nec-1 inactive (Nec-1i), its inactive variant, and Nec-1 stable (Nec-1s), its more stable variant. We report that Nec-1 is identical to methyl-thiohydantoin-tryptophan, an inhibitor of the potent immunomodulatory enzyme indoleamine 2,3-dioxygenase (IDO). Both Nec-1 and Nec-1i inhibited human IDO, but Nec-1s did not, as predicted by molecular modeling. Therefore, Nec-1s is a more specific RIPK1 inhibitor lacking the IDO-targeting effect. Next, although Nec-1i was ∼100 × less effective than Nec-1 in inhibiting human RIPK1 kinase activity in vitro, it was only 10 times less potent than Nec-1 and Nec-1s in a mouse necroptosis assay and became even equipotent at high concentrations. Along the same line, in vivo, high doses of Nec-1, Nec-1i and Nec-1s prevented tumor necrosis factor (TNF)-induced mortality equally well, excluding the use of Nec-1i as an inactive control. Paradoxically, low doses of Nec-1 or Nec-1i, but not Nec -1s, even sensitized mice to TNF-induced mortality. Importantly, Nec-1s did not exhibit this low dose toxicity, stressing again the preferred use of Nec-1s in vivo. Our findings have important implications for the interpretation of Nec-1-based data in experimental disease models.