Genomic organization of the 5' region of the human thyroglobulin gene

OBJECTIVE: The purpose of the present work is to establish the intron-exon organization from exon 12 to exon 23 of the human thyroglobulin gene and to construct a physical map of the 5' terminal half of the gene. DESIGN: Screening of a genomic library and subsequent restriction map, hybridization and sequencing methods have been employed to characterize the recombinant positive phages. METHODS: A human genomic DNA library was screened by in situ hybridization. Southern blotting experiments were performed to characterize the phage inserts. Intron/exon junction sequences were determined by the Taq polymerase-based chain terminator method. Finally, the thyroglobulin gene was mapped using the Gene Bridge 4 radiation hybrid clone panel. RESULTS: We isolated and characterized four lambda phage clones that include nucleotides 3002 to 4816 of the thyroglobulin mRNA, encompassing exons 12 to 23 of the gene. The exon sizes range between 78 and 219 nucleotides. We found that the GT-AG splicing sequences rule was perfectly respected in all the introns. A total of 7302 intronic bases was analyzed. Hormogenic tyrosine 5 and 1291 are encoded by exons 2 and 18. Also, seven alternative spliced variants are associated with the 5' region. Thyroglobulin gene maps to 5,5 centiRays from the AFMA053XF1 marker, in chromosome 8. CONCLUSIONS: The present study shows that the first 4857 bases of thyroglobulin mRNA are divided into 23 exons and the four phages isolated include 32.6 kb genomic DNA, covering 1815 nucleotides of exonic sequence distributed in 12 exons, from exon 12 to 23.     

Genomic organization of the 3' region of the human thyroglobulin gene.

The genomic organization of the 3' end of the human Thyroglobulin (Tg) gene has not previously been characterized. We isolated and characterized seventeen lambda phage clones from a human genomic library that included nucleotides 6263 to 8410 of the Tg mRNA, encompassing the last thirteen 3' exons of the Tg gene. The region contained exons ranging in size from 94 to 222 nucleotides, split by introns of 1 to 64 kb. We estimate a total of 48 exons in the Tg gene. All the intron-exon boundaries were sequenced. We found that the splicing sequences diverged considerably from the 3' and 5' consensus. However, the GT-AG rule was perfectly respected in all the exons. A total of 5788 intronic bases and most of the sequences contained in the 13 exons were analyzed (1846 bases). One sequence variation, TT to CC at positions 8377-8378, was found in the 3' untranslated segment. The three tyrosine residues involved in thyroid hormones synthesis (amino acids 2554, 2568, and 2747) at the carbosyl termini of Tg, are encoded by exons 44, 45, and 48. The knowledge of the precise organization of the Tg gene should help to direct studies of Tg gene mutations in families in which a defect in the synthesis of Tg occurs.     

mRNA in human cells contains sequences complementary to the Alu family of repeated DNA.

Approximately one-half of the polysomal poly(A)+RNA from CCRF-CEM human lymphoblastoid cells associates at low R0t (10 M.sec) [where R0 is the initial concentration of RNA (M) and t is time (sec)] to form branched complexes detectable by electron microscopy. The complexes typically involve 2-16 molecules associated over double-stranded regions 120 +/- 30 base pairs long. Formation of such complexes suggests that poly(A)+RNA contains repeated-sequence elements that are highly represented in the mRNA population. Hybridization of polysomal poly(A)+RNA with a recombinant human DNA plasmid, p lambda H15C, which is shown to contain at least three regions complementary to two different members of the Alu family of DNA repeat sequences, showed a total of five regions where R loops are formed. The hybridized regions comprising these groups are 260 +/- 180, 240 +/- 170, 150 +/- 70, 180 +/- 60, and 180 +/- 80 base pairs long. The relative frequencies of R loops formed at these different sites indicate that sequences in this recombinant DNA are represented in the mRNA population at different frequencies. The hybridizing sequence of the RNA molecules is located near one terminus in 13% of the R loops and internally in 53% of the R loops. Surprisingly, 35% of the R loops apparently involve RNA molecules hybridized over their entire length of only 200 +/- 110 base pairs.     

Partial deletion of the 5' beta-globin gene region causes beta zero- thalassemia in members of an American black family

Restriction endonuclease mapping defined a partial deletion of about 1.35 kb in the beta-globin gene of a black American patient with hemoglobin S-beta zero-thalassemia and in his uncle with a beta zero- thalassemia trait. The 5' endpoint of the deletion is about 600 bases upstream from the cap site, and the 3' endpoint lies within about 500 bases from the 5' splice junction of the second intervening sequence. The deletion is different from that of a previously reported Indian beta zero-thalassemia allele, where 0.6 kb is deleted at the 3' end of the beta-globin gene.     

Monoallelic deletion in the 5' region of the thyroglobulin gene as a cause of sporadic nonendemic simple goiter.

The cause of sporadic simple goiter is unknown in most cases. Family studies have suggested that this disorder may have a genetic component in some patients. We have previously demonstrated that some cases of endemic and nonendemic simple goiter are associated with a mutation within exon 10 of the thyroglobulin gene. Here we report a study of 50 cases diagnosed as having nonendemic simple goiter, and found 1 case with a large heterozygous deletion within the thyroglobulin gene. The deletion involves the promoter region and the 11 first exons of this gene and is associated with a euthyroid state. We hypothesize that the absence of thyroglobulin synthesis from the deleted allele may be responsible for a decreased level of thyroglobulin mRNA. Euthyroidism would be achieved by thyrotropin (TSH) stimulation but at the expense of goiter development.     

Molecular evolution of the human adult alpha-globin-like gene region: insertion and deletion of Alu family repeats and non-Alu DNA sequences.

Previous heteroduplex studies have revealed extensive sequence homology between the two human adult alpha-globin-like genes (alpha 2 and alpha 1) and their flanking regions. These homologous regions, which are interrupted by two blocks of nonhomology, each span approximately 4 kilobases [Lauer, J., Shen, C.-K. J. & Maniatis, T. (1980) Cell 20, 119-130]. We have determined 3 kilobases of DNA sequences within and flanking the nonhomologous blocks of these two tandem duplication units. A total of three Alu family repeats has been identified. Two of them are approximately 300 base pairs long and define the 3' ends of the first homology blocks. The third Alu family member is a 600-base-pair-long sequence consisting of two monomeric Alu members arranged in a head-to-tail fashion. It is located in the 3' portion of the first block of nonhomology in alpha 2-gene-containing unit. We present direct evidence that this dimeric Alu sequence was inserted at a staggered break. The second nonhomology block is the result of insertion or deletion of a 224-base-pair sequence. From these data and the calculation of sequence divergence, we propose a history for the evolution of the human adult alpha-globin-like gene region. We also suggest that DNA insertion elements may disrupt gene correction processes in the two duplication units containing alpha 2- and alpha 1-globin genes.     

Human cytochrome P-450 4 mRNA and gene: part of a multigene family that contains Alu sequences in its mRNA.

Several overlapping lambda gt11 cDNA clones have been sequenced and shown to encode for the full-length human cytochrome P-450 4. The structure and location of the exons and flanking intron regions were also identified from a lambda EMBL-3 human genomic clone that encodes the full-length human P-450 4 gene. The human P-450 4 mRNA is flanked by 62 base pairs of 5'- and 1508 base pairs of 3'-noncoding sequence, with 1548 bases that encode a protein of 516 amino acids (Mr, 58,376). The predicted amino acid sequence of human P-450 4 is 69% and 70% homologous to its equivalent in mouse and rat, respectively, 75% homologous to rabbit P-450 4, and 68% homologous to human P1-450. The 7.6-kilobase gene encodes 3118 nucleotides of exon sequence that is separated by six introns into seven exons. Exon 7, which is 1802 nucleotides, contains three inverse/complement Alu sequences that are organized in tandem. Comparison of the genomic DNA sequence of the human P-450 4 gene with the human P1-450 and related genes in rat and mouse and the identification of the amino acid residues and triplet codon at each exon-intron junction show that the location of each intron in the human P-450 4 gene is conserved within this gene family. Although the length and homology of the introns within a related gene family may not be conserved, the location of intronic sequences may be an important determinant in the identification of related P-450 genes.     

Phenotypic variation among four family members with congenital hypothyroidism caused by two distinct thyroglobulin gene mutations

BACKGROUND: Thyroglobulin (Tg) is a large glycoprotein that is intimately involved in the biosynthesis of thyroxine and triiodothyronine. At least 38 mutations have been described in the Tg gene that are associated with varying degrees of hypothyroidism. We studied the Tg gene in four related subjects with congenital hypothyroidism. SUMMARY: We found a novel compound heterozygous constellation (IVS30 + 1G>T/A2215D) in a brother and sister and one previously described related mutation (IVS30+1G>T) in their two sibling second degree cousins. The brother with the IVS30 + 1G>T/A2215D mutation and the two siblings with the IVS30+1G>T mutation had fetal or neonatal goiter and all had hypothyroidism. CONCLUSIONS: This study further confirms the association of the IVS30+G>T mutation of the Tg gene with hypothyroidism. Computer analysis predicts that the A2215D mutation, first reported here, should cause structural instability of Tg but when present as a compound heterozygous mutation with IVS30+G>T/A its effect is unclear but is likely to be influenced by iodine intake.     

The complete structure of the rat thyroglobulin gene.

We have isolated the entire gene for rat thyroglobulin, the precursor for thyroid hormone biosynthesis. The gene is at least 170,000 base pairs (bp) long; 9000 bp of coding information are distributed in 42 exons of homogeneous size (150-200 bp) except for two exons of 1100 and 620 bp. The sequences coding for two major thyroxine-forming sites are localized in exons 2 and 39. These two sequences do not show any homology either at the DNA or at the protein-sequence level, even though they code for sites highly specialized for the same function. Furthermore, both the 3' and the 5' end of the thyroglobulin structural gene appear to be made of repetitive units, which again do not show any homology. On the basis of these observations, we propose that the thyroglobulin gene arose by shuffling of at least two segments, with different evolutionary histories, each of which already contained introns.