Monoallelic expression of mutant thyroid peroxidase allele causing total iodide organification defect

Mutations in the thyroid peroxidase (TPO) gene lead to severe congenital hypothyroidism due to total iodide organification defect (TIOD). According to the recessive mode of inheritance, patients are homozygous or compound heterozygous for gene mutations. However, about 17% of cases with typical phenotype harbor a single TPO-mutated allele. We present a TIOD family in which the three affected siblings had a single genomic TPO mutation (R693W) inherited from the unaffected father. Other mutations were not found, although all TPO coding exons and exon/intron boundaries were sequenced. Eleven different polymorphisms were found in hetero- or homozygosity in all family members. On the contrary, using retrotranscribed thyroid tissue RNA, all heterozygous polymorphisms and the mutation were homozygous. The distribution of the polymorphisms indicated that only the mutant paternal allele is transcribed at the thyroid tissue level. We excluded the presence of major deletions involving the maternal chromosome at 2p25 and of maternal imprinting or mutations in part of the regulatory regions of the gene. In summary, we report one family with TIOD due to monoallelic expression of a mutant TPO allele in the thyroid. This mechanism might be generally involved in TIOD cases with a single TPO-mutated allele.     

Thyroperoxidase gene mutations in congenital goitrous hypothyroidism with total and partial iodide organification defect.

Mutations of the thyroperoxidase (TPO) gene have been reported as being the most severe and frequent abnormality in thyroid iodide organification defect (IOD) causing goitrous congenital hypothyroidism. The objective of this study was to screen and subsequently identify TPO gene mutations in patients with congenital hypothyroidism with evidence of total iodine organification defects (TIOD) or partial iodine organification defect (PIOD) as defined by the perchlorate discharge test. Seven goitrous patients with TIOD and seven patients with PIOD, from three and five unrelated families, respectively, were studied. We were able to detect different TPO genes mutations in patients with TIOD and PIOD. In TIOD families the results were as follows: (1) a homozygous GGCC insertion at exon 8, position 1277 (family 1); (2) compound heterozygosity with a GGCC insertion at exon 8 (1277) and a nucleotide substitution in exon 11 (2068G>C) (family 2); (3) compound heterozygosity with the mutation 2068G>C in exon 11 and a C insertion in exon 14 between positions 2505-2511 (family 3). In patients with PIOD we have detected: (1) only one heterozygous mutation in two families (4 and 5), in exons 11 and 10 (2084G>A and 1780C>A); (2) a compound heterozygous condition in one family (family 6), with mutations, respectively in exons 8 and 10 (1242G>T and 1780C>A); (3) only polymorphisms (family VII) and (4) a heterozygous mutation in the first base of the border exon/intron 9 +1G>T (family VIII). We did not detect inactivating mutations in exons 11, 16, and 21 of the THOX2 gene where mutations have been previously described. We concluded that homozygous and compound heterozygous mutations found in TIOD characterized the autosomal recessive mode of inheritance and will translate a nonfunctional protein or a protein that may not reach the apical membrane. As for PIOD, the majority of the studied kindreds had only heterozygous mutations and/or polymorphisms. It is conceivable that these TPO gene sequence alterations may partially affect the functional state of the translated protein or affect its transport to the apical membrane.     

Monoallelic thyroid peroxidase gene mutation in a patient with congenital hypothyroidism with total iodide organification defect

The aim of this study was to identify the genetic defect of a patient with dyshormonogenetic congenital hypothyroidisms (CH) with total iodide organification defect (TIOD). A male child diagnosed with CH during neonatal screening. Laboratory tests confirmed the permanent and severe CH with TIOD (99% perchlorate release). The coding sequence of TPO, DUOX2, and DUOXA2 genes and 2957 base pairs (bp) of the TPO promoter were sequenced. Molecular analysis of patient's DNA identified the heterozygous duplication GGCC (c.1186_1187insGGCC) in exon 8 of the TPO gene. No additional mutation was detected either in the TPO gene, TPO promoter, DUOX2 or DUOXA2 genes. We have described a patient with a clear TIOD causing severe goitrous CH due to a monoallelic TPO mutation. A plausible explanation for the association between an autosomal recessive disorder with a single TPO-mutated allele is the presence of monoallelic TPO expression.     

Two decades of screening for congenital hypothyroidism in The Netherlands: TPO gene mutations in total iodide organification defects (an update)

Presented is a cohort study to assess the nature and frequency of thyroid peroxidase (TPO) mutations in 45 patients (35 families) with congenital hypothyroidism due to a total iodide organification defect; incidence is 1:66,000 in The Netherlands. The presentation is consistently similar with a severe form of congenital hypothyroidism and also characterized by a complete and immediate release of accumulated radioiodide from the thyroid after sodium perchlorate administration. Sixteen different mutations were found, including eight novel mutations; the majority occurs in exons 8, 9, or 10. The GGCC insertion in exon 8 at nucleotide 1277, leading to an early termination signal in exon 9, is the most frequently occurring mutation. These mutations were detected in 29 families in both TPO alleles (13 homozygous and 16 compound heterozygous). In one family, partial maternal isodisomy of 2p was detected, in four families only one mutated TPO allele could be detected, and in one family no inactivating TPO mutation could be found. Because all patients clearly had the clinicopathologic features of a total iodide organification defect, we conclude that in these five families the mutations in the (other) alleles could be either located in the intronic sequences or in the promoter region. Mutations in the TPO gene result in total iodide organification defects.     

Mutation analysis of thyroid peroxidase gene in Chinese patients with total iodide organification defect: identification of five novel mutations

Total iodide organification defect (TIOD), where the iodide in the thyroid gland cannot be oxidized and/or bound to the protein, is caused by a defect in the thyroid peroxidase (TPO) gene. Single strand conformation polymorphism analysis was used to screen for mutations in the TPO gene from five unrelated TIOD patients in Taiwan, and five novel mutations were detected. Three of these were frameshift mutations: a single T insertion between nucleotide position 2268 and 2269 (c.2268-2269 insT) in exon 13 and two single C deletions at nucleotide positions 843 (c.843 delC) and 2413 (c.2413 delC) in exon 8 and 14 respectively. The other two were single nucleotide substitutions (c.G1477>A and c.G2386>T) located in exons 9 and 13 respectively. While the former would result in amino acid substitution (Gly493Ser) in the highly conserved region of the TPO polypeptide, the latter would result in either amino acid substitution (Asp796Tyr) or alternative splicing. Of those identified TPO mutations, c.2268-2269 insT was most prevalent and was detected as heterozygous in all but one TIOD patients. All five TIOD patients investigated in this study were compound heterozygous. The method presented in this study could be used for carrier assessment and mutation analysis of newly identified TIOD patients.     

Maternal isodisomy for chromosome 2p causing severe congenital hypothyroidism

Severe congenital hypothyroidism (CH) due to a total iodide organification defect (TIOD) is usually due to mutations in the thyroid peroxidase (TPO) gene located at chromosome 2p25. A homozygous deletion [DeltaT2512 (codon 808)] in exon 14 was identified in a patient with classical TIOD. The transmission pattern of the TPO gene in this family was anomalous; the mother was heterozygous for the deletion; and the mutation was absent in the father. Polymorphic short tandem repeat (STR) markers confirmed paternity and demonstrated on chromosome 2 that the propositus was homozygous for most markers on chromosome 2p and that these were identical to one of the maternal 2p homologs. A normal karyotype was found in the propositus, his parents and sister. We conclude that the homozygosity in the patient is due to partial maternal isodisomy of the short arm of chromosome 2, carrying a defective TPO gene. The patient, born small for gestational age, develops and grows well and appears healthy (while being treated with thyroxine) and has a normal phenotype except for a unilateral preauricular skin tag. This shows that partial maternal isodisomy for chromosome 2p (2pter - 2p12) is compatible with a minimal influence on normal development.     

High prevalence of a novel mutation (2268 insT) of the thyroid peroxidase gene in Taiwanese patients with total iodide organification defect,and evidence for a founder effect

The mutation of the thyroid peroxidase (TPO) gene that causes the total iodide organification defect (TIOD) is a common and severe condition leading to dyshormonogenesis of the thyroid gland in Caucasians. However, the role of TIOD in Chinese patients with thyroid dyshormonogenesis is unknown. In this study we followed 16 patients from 16 unrelated families in Taiwan and performed perchlorate discharge examination. Seven patients had TIOD and 2 had the partial iodine organification defect (PIOD) among the 16 families. These 9 patients underwent screening in search of TPO gene mutations. Three new mutations (2268 insT, 2243 delT, and G157C) were detected in the 7 patients with TIOD, whereas no mutation in the TPO gene was found in the 2 patients with PIOD. The 2268 insT mutation was noted to be the most common among these TIOD patients (12 of 14 studied alleles, 86%). With 3 intragenic polymorphic markers, we found that the alleles carrying the 2268 insT mutation in Taiwan Chinese TIOD patients were tightly linked to a specific haplotype. The allele frequencies of this haplotype in the 8 patients with homozygous 2268 insT (5 unrelated families, 10 studied alleles) and in 49 normal individuals (98 studied alleles) were 1.00 and 0.02, respectively (P < 0.0001). This indicates that this common novel mutation among Taiwanese patients with TIOD is due to a founder effect.     

A novel mutation in the TPO gene in goitrous hypothyroid patients with iodide organification defect

OBJECTIVE: To screen and subsequently sequence the TPO gene for mutations in patients with congenital goitre, hypothyroidism and evidence for an organification defect (positive perchlorate discharge test). PATIENTS: We have studied seven hypothyroid and congenitally goitrous patients from three unrelated families. DESIGN AND MEASUREMENTS: We have measured serum thyroid hormone levels, 131I uptake, serum TSH and serum Tg concentrations. Denaturing gradient gel electrophoresis (DGGE) of PCR amplified genomic DNA was used to screen for mutations in the TPO gene. RESULTS: DGGE identified the presence of two frameshift mutations: a GGCC duplication in exon 8 (homozygous in one family and heterozygous in the other family) and a heterozygous insertion of a single nucleotide (C) at position 2505-2511 in exon 14. In addition, we have detected an alteration in exon 11, not yet described in the literature, derived from a single nucleotide substitution of a C to G at position 2008, altering the well-conserved amino acid domain among the peroxidases superfamily. This mutation in exon 11 was present in two families that showed heterozygous mutation for exon 8 or for exon 14. CONCLUSIONS: These results could support the hypothesis for a putative compound heterozygosity pattern in the affected patients. The altered phenotype (goitre and hypothyroidism since birth) seems justifiable in view of the possible inactivating character of this novel mutation in exon 11.     

Goitrous congenital hypothyroidism and hearing impairment associated with mutations in the TPO and SLC26A4/PDS genes

CONTEXT: Pendred syndrome (PS) and thyroid peroxidase (TPO) deficiency are autosomal-recessive disorders that result in thyroid dyshormonogenesis. They share congenital hypothyroidism, goiter, and an iodide organification defect as common features. Whereas the hallmark of PS is sensorineural deafness, other forms of congenital hypothyroidism may also lead to hearing impairment. Therefore, a definite diagnosis may be difficult and require molecular genetic analyses. CASE REPORT: The propositus presented at birth with primary hypothyroidism and goiter. He also had congenital bilateral moderate hearing loss, and PS was suspected. METHODS: We sequenced the SLC26A4/PDS and TPO genes in the propositus and tested familial segregation of mutations in all available family members who were phenotypically normal. The functional consequences of the identified pendrin mutation (p.R776C) were studied in vitro. RESULTS: Sequencing of the SLC26A4/PDS gene revealed a single monoallelic missense mutation in the propositus (p.R776C). This mutation, which was inherited from his unaffected mother, has previously been identified in an individual with deafness and an enlarged vestibular aqueduct. Sequencing of the TPO gene revealed compound heterozygosity for a novel nonsense mutation (p.Q235X) and a known missense mutation (p.Y453D). The mutant pendrin (p.R776C) retained its ability to transport iodide in vitro. CONCLUSIONS: These results show that the propositus carries three sequence variants in two genes: a monoallelic SLC26A4/PDS sequence variant and compound heterozygous TPO mutations. Our study illustrates that if only a single heterozygous SLC26A4/PDS mutation is found in a patient with goiter and deafness, other genetic explanations should be considered.     

Novel mutations of the thyroid peroxidase gene in patients with permanent congenital hypothyroidism.

OBJECTIVE: It is suggested that iodide organification defects account for 10% of all cases with congenital hypothyroidism (CH). One candidate gene for these defects is the thyroid peroxidase (TPO) gene. DESIGN: Exons 2, 8-10 and 14 of the TPO gene were examined in 30 patients with permanent CH without a family history of CH. This group was characterized by the presence of an orthotopic thyroid gland and elevated TSH levels. METHODS: The mutational screening was performed by single-strand conformational polymorphism followed by sequence analysis of fragments with abnormal migration patterns and by restriction enzyme analysis. RESULTS: In four patients we were able to identify mutations on both alleles which have not been described so far. One patient was a carrier of a new homozygous point mutation in exon 9 resulting in an exchange from Leu to Pro at codon 458. Another patient was found to be compound heterozygous for two mutations, a 20 bp duplication in exon 2 and a new mutation in exon 9 (Arg491His). Two brothers of consanguineous parents showed a homozygous T deletion in exon 14 at position 2512. CONCLUSIONS: Our findings confirm the genetic heterogeneity of TPO defects and support the suggested prevalence of organification defects.     

Two novel mutations in the thyroid peroxidase gene with goitrous hypothyroidism

We encountered a Japanese patient with goitrous hypothyroidism due to iodide organification defect in the thyroid gland. Sequence analysis identified two novel mutations (E378K in exon 8 and a heterozygous 10 base deletion of the intron 15-exon 16 boundary) in the thyroid peroxidase (TPO) gene. As individuals with goitrous hypothyroidism caused by TPO gene mutation develop thyroid cancer, regular and careful follow-up for such patients must be done.     

A Homozygous Nonsense Thyroid Peroxidase Mutation (R540X) Consistently Causes Congenital Hypothyroidism in Two Siblings Born to a Consanguineous Family

Objective:

Congenital hypothyroidism (CH) is the most common neonatal endocrine disorder, and mutations in the thyroid peroxidase (TPO) gene have been reported to cause the disease. Our aim in this study was to determine the genetic basis of CH in two affected children coming from a consanguineous family.

Methods:

First, we investigated the potential genetic linkage of the family to any known CH locus using microsatellite markers and then screened for mutations in the linked gene by Sanger sequencing. By using next-generation sequencing, we also checked if any other mutation was present in the remaining 10 causative CH genes.

Results:

The family showed potential linkage to the TPO gene, and we detected a homozygous nonsense mutation (R540X) in both cases. The two patients had total iodide organification defect (TIOD). Both the microsatellite marker haplotypes and the mutation segregated with the disease status in the family, i.e. all healthy subjects were either heterozygous carriers or homozygous wild-type, confirming the pathogenic nature of the mutation. Neither was the mutation present in any of the 400 control chromosomes nor were there any other mutations in the remaining causative CH genes.

Conclusion:

This study proves the pathogenicity of R540X mutation and demonstrates the strong genotype/phenotype correlation associated with this mutation. It also highlights the power of working with familial cases in revealing the molecular basis of CH and in establishing accurate genotype/phenotype relationships associated with disease causing mutations.     

Two compound heterozygous mutations (c.215delA/c.2422T-->C and c.387delC/c.1159G-->A) in the thyroid peroxidase gene responsible for congenital goitre and iodide organification defect

BACKGROUND: Iodide organification defects are frequently but not always associated with mutations in the thyroid peroxidase (TPO) gene and characterized by a positive perchlorate discharge test. These mutations phenotypically produce a congenital goitrous hypothyroidism, with an autosomal recessive mode of inheritance. OBJECTIVES: In the present study we extended our initial molecular studies in six unrelated patients heterozygous for the TPO mutations, in order to identify the second mutation in this autosomal recessive disease. METHODS: The promoter and the complete coding regions of the human TPO and DUOXA2 genes, along with the flanking regions of each intron were analysed by direct DNA sequencing. RESULTS: Four different inactivating TPO mutations were identified in two patients: two novel mutations (c.215delA [p.Q72fsX86] and c.1159G-->A [p.G387R]) and two previously reported (c.387delC [p.N129fsX208] and c.2422T-->C [p.C808R]), confirming the inheritance of two different compound heterozygous mutations, c.215delA/c.2422T-->C and c.387delC/c.1159G-->A. The remaining four patients did not show additional inactivating mutations in the TPO gene and all had only the wild type sequencing in the DUOXA2 gene. CONCLUSIONS: We have reported two patients with iodide organification defect caused by two compound heterozygous mutations, c.215delA/c.2422T-->C [p.Q72fsX86/p.C808R] and c.387delC/c.1159G-->A [p.N129fsX208/p.G387R], in the TPO gene and four patients with monoallelic TPO defect. Identification of the molecular basis of this disorder might be helpful for understanding the pathophysiology of congenital hypothyroidism.     

Two different mutations in the thyroid peroxidase gene of a large inbred Amish kindred: power and limits of homozygosity mapping

Approximately 10% of newborns with congenital hypothyroidism are unable to convert iodide into organic iodine. This iodide organification defect has a prevalence of 1 in 40,000 newborns and may be caused by defects in the thyroid peroxidase enzyme (TPO), the hydrogen peroxide-generating system, the TPO substrate thyroglobulin, or inhibitors of TPO. We identified a high incidence of severe hypothyroidism due to a complete iodide organification defect in the youngest generation of five nuclear families belonging to an inbred Amish kindred. Genealogical records permitted us to trace their origin to an ancestral couple 7-8 generations back and to identify an autosomal recessive pattern of inheritance. Initial studies of homozygosity by descent using two polymorphic markers within the TPO gene showed no linkage to the phenotype. In fact, 4 of 15 affected siblings from 2 of the nuclear families were heterozygous, resulting in homozygosity values of 73% and 53% in affected and unaffected family members, respectively. A genome-wide homozygosity screen using DNA pools from affected and unaffected family members localized the defect to a locus close to the TPO gene. Linkage analysis using 4 additional polymorphic markers within the TPO gene reduced the number of homozygous unaffected siblings to zero without altering the percent homozygosity initially found in the affected. Sequencing of the TPO gene revealed 2 missense mutations, E799K and R648Q. TPO 779K was found in both alleles of the 11 affected homozygotes, both mutations were present in each of the 3 affected compound heterozygotes, and there were no TPO mutations in 1 subject with hypothyroidism of different etiology. These results demonstrate the power of the DNA pooling strategy in the localization of a defective gene and the pitfalls of linkage analysis when 2 relatively rare mutations coexist in an inbred population.     

Molecular analysis of the PDS gene in a nonconsanguineous Sicilian family with Pendred's syndrome.

OBJECTIVE: The autosomal recessive Pendred's syndrome is defined by congenital sensorineural deafness, goiter, and impaired iodide organification. It is caused by mutations in the Pendred's syndrome (PDS) gene that encodes pendrin, a chloride/iodide transporter expressed in the thyroid, the inner ear, and the kidney. In this study we performed clinical and molecular analyses in three siblings from a nonconsanguineous Sicilian family who presented with the clinical features of Pendred's syndrome. PATIENTS AND MOLECULAR ANALYSES: In two sisters and one brother, the clinical diagnosis of Pendred's syndrome was established based on the findings of sensorineural hearing loss and large goiters. Thyroid function tests, perchlorate discharge tests, thyroid ultrasound, and scintigraphy were performed in all affected individuals. Exons 2 to 21 of the PDS gene were amplified by polymerase chain reaction (PCR) and both strands were submitted to direct sequence analysis. RESULTS: The clinical diagnosis of Pendred's syndrome was supported by a positive perchlorate discharge test in the three afflicted siblings. Direct sequence analysis of the PDS gene revealed that all three harbored one allele with a novel mutation 890delC leading to a frameshift mutation and premature stop codon at position 302 (FS297 > 302X). On the other allele, two of the siblings had a previously described transition 1226G > A, which results in the substitution of arginine by histidine at position 409 (R409H). In the index patient, no mutation could be identified on the other allele. In functional studies, these mutants lose the ability of pendrin to mediate iodide efflux. CONCLUSIONS: All three patients included in this study presented with the classic Pendred syndrome triad. Two siblings were compound heterozygous for mutations in the coding region of the PDS gene. The third individual could have an unidentified mutation in a regulatory or intronic region of the PDS gene, or an identical phenotype caused by distinct pathogenic mechanisms.     

Clinical and molecular analysis of three Mexican families with Pendred's syndrome

BACKGROUND: The autosomal recessive Pendred's syndrome is defined by congenital sensorineural deafness, goiter, and impaired iodide organification. It is caused by mutations in the Pendred's syndrome (PDS) gene that encodes pendrin, a chloride/iodide transporter expressed in the thyroid, the inner ear, and the kidney. OBJECTIVE: To perform a detailed clinical and molecular analysis of patients with Pendred's syndrome from four patients from three unrelated Mexican families. METHODS: Thyroid function tests, perchlorate test, thyroid scintigraphy, audiometry, computer tomography and magnetic resonance imaging were performed in all affected individuals. Haplotype analyses were performed using microsatellite markers flanking the PDS locus, and the PDS gene was submitted to direct sequence analysis. RESULTS: All patients presented with sensorineural deafness, Mondini malformations of the cochlea, an enlarged vestibular aqueduct, goiter, and a positive perchlorate test. Two patients were hypothyroid, two individuals were euthyroid. Sequence analysis revealed a complex homozygous deletion/insertion mutation at the end of exon 4 in the index patient of family 1 resulting in a premature stop codon at position 138. In family 2, the affected individuals were compound heterozygous for a splice acceptor mutation (IVS2 -1G>A) and a 1231G>C transversion substituting alanine 411 by proline (A411P). In family 3, the index patient was found to be homozygous for a transversion 412G>T in exon 4 replacing valine 138 by phenylalanine (V138F). CONCLUSIONS: All patients included in this study presented with the classic Pendred syndrome triad and molecular analysis revealed pendrin mutations as the underlying cause. The identification of three novel mutations, one of them of complex structure, expands the spectrum of mutations in the PDS gene and emphasizes that they display marked allelic heterogeneity.     

A novel mutation in the pendrin gene associated with Pendred's syndrome

OBJECTIVE: Pendred's syndrome is an autosomal recessive disorder characterized by goitre, sensorineural deafness and iodide organification defect. It is one of the most frequent causes of congenital deafness, accounting for about 10% of hereditary hearing loss. It is caused by mutations in the pendrin (PDS) gene, a 21 exon gene located on chromosome 7. The aim of this study was to examine an Italian family affected with Pendred's syndrome at the molecular level. PATIENTS: Thirteen subjects belonging to a family from Southern Italy were evaluated for the clinical and genetic features of Pendred's syndrome. MEASUREMENTS: Exons 2-21 of the PDS gene were amplified from peripheral leucocytes by the polymerase chain reaction; mutation analysis was performed by single strand conformation polymorphism, direct sequencing and restriction analysis. RESULTS: The index patient had the classical triad of the syndrome and harboured two mutations in the PDS gene in the form of compound heterozygosity. He was found to be heterozygous for a cytosine to adenosine mutation at nucleotide 1523 in exon 13 and for a IVS 1001 + 1G --> A mutation. The former is a novel mutation which results in a change of 508 threonine to asparagine in the putative eleventh transmembrane domain. The latter mutation in the donor splice site has already been described in other patients and is thought to lead to aberrant splicing and premature protein truncation. Three subjects who were heterozygous for one mutation had normal phenotypes. Two subjects had sensorineural deafness and were heterozygous for a single mutation. Goitre was found only in patients with Pendred's syndrome and was absent in all other individuals, albeit residing in an iodine-deficient area. CONCLUSIONS: We have identified a novel mutation in the pendrin gene causing Pendred's syndrome, and confirm that molecular analysis is a useful tool for a definitive diagnosis. This is particularly relevant in cases such as in the subjects of our family in which the clinical features might be misleading and other genetics factors might be responsible for deafness.     

Analysis of the SLC26A4 gene in patients with Pendred syndrome in Taiwan

Pendred syndrome (PS) is an autosomal recessive disease that is characterized by congenital sensorineural hearing loss, goiter, and a partial iodine organification defect. In this study, we characterized the thyroid status and identified mutations in the SLC26A4 gene in Chinese subjects with PS. We evaluated 7 unrelated Chinese subjects who had PS. Biochemical analysis, formal audiogram, ultrasonography of the thyroid gland, perchlorate discharge test, computerized tomography scan of the vestibular aqueducts, and DNA sequence analysis of SLC26A4 were performed. Levels of thyroid hormones were essentially normal in all patients: 2 patients had goiters and/or elevated serum thyroglobulin levels, whereas 2 other patients had positive thyroid antibodies and a positive perchlorate discharge test. We identified SLC26A4 gene mutations in 6 of 7 probands and their affected relatives. The affected subjects in family I was compound heterozygous for 2 missense mutations: a mutation in exon 9 (1079C>T) that resulted in the replacement of alanine by valine at codon 360 (A360V) and a mutation in exon 19 (2168A>G) that resulted in the replacement of histidine by arginine at codon 723 (H723R). The affected subjects in families II and III all were homozygous for a mutation in intron 7. The probands IV and V were compound heterozygotes for the mutation in intron 7 and in exon 19, and the proband VI was compound heterozygous for the intron 7 mutation and a missense mutation in exon 12 (1343C>T) that resulted in the replacement of serine by leucine at codon 448 (S448L). One novel mutation was identified (A360V). We identified biallelic mutations in the SLC26A4 gene in 6 of 7 probands with PS in Taiwan, including a novel missense mutation. The mild thyroid dysfunction in these patients suggests that PS should be considered in all patients with congenital or early-onset hearing impairment.     

Loss of heterozygocity at the thyroid peroxidase gene locus in solitary cold thyroid nodules.

Germline mutations in both alleles of the thyroid peroxidase (TPO) gene have been reported as a frequent cause of congenital hypothyroidism resulting from a total iodide organification defect (TIOD). Because TPO mutations have a prevalence of 1 in 66,000 newborns and is inherited in an autosomal recessive mode the frequency of a heterozygous germline mutation in the TPO gene should reach about 1 in 260 in the population. A somatic TPO mutation coinciding with a somatic loss of one of the TPO alleles or a TPO germline mutation could lead to somatic loss of TPO activity with impairment of thyroid hormone synthesis and decrease of growth control. The latter would lead to increased thyroid epithelial cell proliferation and the subsequent development of a scintigraphically cold thyroid nodule (CTN). To test this hypothesis we studied 40 CTN for the presence of mutations or loss of heterozygosity (LOH) in the TPO gene. For comparisons we also studied LOH in 17 autonomously functioning thyroid nodules (AFTN). Genomic DNA was extracted from nodular and surrounding tissue, polymerase chain reaction (PCR) amplified, sequenced, and analyzed for LOH. In 6 CTNs of 37 informative cases we detected LOH using the genomic markers sRA, D2S2268, and D2S319 within or near the TPO gene locus (2p24-25). In contrast, a genomic marker closer to the centromer (D2S144, 2p24-21) shows LOH in only 1 CTN. We did not detect LOH in AFTN. In none of the cases a germline or somatic mutation in the TPO gene was detectable in the TPO gene. LOH in 6 of 37 CTNs suggests that genetic defects at the TPO or the chromosomal locus 2p24-25 might play a role in the etiology of CTNs. However, we did not find the combination of LOH with a somatic mutation in the TPO gene. It is therefore likely that a gene defect near the TPO locus is part of the neoplastic process in a subgroup of CTNs.     

The C–T substitution in the distal CACCC box of the β-globin gene promoter is a common cause of silent β thalassaemia in the Italian population

This paper describes four families of Italian descent in each of which the propositus had the clinical phenotype of thalassaemia intermedia, resulting from the compound heterozygous state for high HbA2 beta thalassaemia and type I silent beta thalassaemia. Direct sequencing on amplified DNA and/or oligonucleotide analysis detected, in all families but one, the compound heterozygous state for codon 39 nonsense mutation and the C-T substitution at position -101 in the distal CACCC box of the beta-globin gene promoter (beta th-101). Members of these families who are heterozygous for high HbA2 beta thalassaemia showed the codon 39 nonsense mutation, while those with the clinical phenotype of silent beta thalassaemia had the beta th-101 mutation. In the remaining family, the propositus and one of his siblings had the compound heterozygous state for a molecularly undefined high HbA2 beta thalassaemia and the beta th-101 mutation in combination with the triple alpha globin gene arrangement. These patients showed a more severe thalassaemia intermedia like clinical phenotype as compared to those with the same beta-globin genotype and a normal alpha-globin gene arrangement. In the families investigated the beta th-101 was always associated with haplotype I. A group of patients with thalassaemia intermedia from Southern Italy, either homozygous or heterozygous for haplotype I and in whom previous studies had failed to define the mutation in one of the beta thalassaemia globin genes, were screened by oligonucleotide analysis for the presence of the beta th-101. Three out of nine were positive. These results indicate that the beta th-101 mutation is a common cause of the type I silent beta thalassaemia phenotype in the Southern Italian population.