Sandbox Reserved 1650

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This Sandbox is Reserved from 26/11/2020, through 26/11/2021 for use in the course "Structural Biology" taught by Bruno Kieffer at the University of Strasbourg, ESBS. This reservation includes Sandbox Reserved 1643 through Sandbox Reserved 1664.

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Human thyroglobulin (TG)

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You may include any references to papers as in: the use of JSmol in Proteopedia ^[1] or to the article describing Jmol ^[2] to the rescue.

Introduction

Human thyroglobulin (TG) is a precursor of tetraiodothyronine or thyroxine (T4) and triiodothyronine (T3), two thyroid hormones (TH). Its structure is essential for the diagnosis, treatment and monitoring of thyroid-related diseases.

1 Synthesis
- 1.1 Role and composition of the thyroid gland
- 1.2 Expression of the TG gene
2 Composition and 3D structure
3 Functions
- 3.1 TH synthesis
  - 3.1.1 Mechanism
  - 3.1.2 Control
- 3.2 Iodine tank
4 Interest in the medical field
- 4.1 Modification of the TG quantity related to the desease
- 4.2 Use of TG to treat deseases

Synthesis

Role and composition of the thyroid gland

The thyroid gland is an endocrine organ located in the neck that secretes HT into the bloodstream. Among them, T4 and T3 are involved in the growth, development and regulation of the metabolism of vertebrates.

The thyroid gland is made up of thyroid vesicles, which are made up of thyroid follicular cells that are arranged around a lumen containing a viscous substance called colloid. The diet is a source of iodide I- ions which, once in the blood, are picked up by the thyroid cells and then partly discharged into the colloid.

Expression of the TG gene

Thyroid follicular cells synthesize human TG via the TG gene on chromosome 8 ^[3]. [d-i]

Composition and 3D structure

Global structure and its acquisition

Once synthesized, the acquisition of the 3D structure of the [>TG ] is enabled by the ER chaperone proteins of the thyroid follicular cells via a slow process ^[4].

The result is a dimeric glycoprotein consisting of 2749 amino acid residues with a molecular weight of 600 kDa. The average size of the dimer is 120x235 Å.

Each of its monomers comprises 5 distinct regions on which approximately (chain A in blue, chain B in green, chain C in dark red, chain D in light red) are distributed. These are the regions :

[>NTD ], [>CORE ], [>FLAP ], [>ARM ] and [>CTD ].

In addition, TG has about 120 cysteine residues allowing the formation of about 60 disulfide bridge bonds per monomer [>Disulfide bridge]. It is therefore a very stable and soluble protein.

Post-translational modifications

TG also undergoes N-glycosylations in the ER at 17 glycosylation sites, so that 10% of its molecular weight is carbohydrate. These modifications enhance its stability and solubility. Indeed, the two monomers are linked not by covalent interactions but via numerous interactions allowed by these N-glycosylations.

Structure of hormonogenic sites

Hormonogenic sites are responsible for the formation of one HT each. They are formed by 2 or even 3 tyrosines at less than 15 Å from each other, and exposed to the solvent. Of these tyrosines, 1 or 2 are acceptors and 1 is a donor.

There are 7 hormonogenic sites for TG :

two , comprising two fixed donor tyrosines Y234 and Y149 and one flexible acceptor tyrosine: T24 [>SIte A] two B sites, including one Y2573 donor and one Y2540 acceptor [>Site B] a C site, comprising both donor and acceptor tyrosine Y2766 two D sites, comprising a Y108 donor and a Y1310 acceptor [>Site D]

An acidic Asp or Glu residue always precedes the acceptor and a lysine is always close to the donor.

Except for site C, donors are at the fixed regions of the dimer while acceptors are at the flexible regions.

Functions

TH synthesis

Mechanism

Once their 3D structure is acquired, TGs are exported into the colloid by exocytosis thanks to their signal peptide which will be cleaved. This extracellular storage increases the amount of TG stored in the body.

In the colloid, about 30 tyrosines out of the 66 tyrosines, each consisting of a phenol group, are iodized. The quantity of iodinated tyrosine depends however on the iodide concentration of the colloid. Indeed, one or two iodide ions can be covalently bound to the colloid and thus give a di (DIT) or mono-iodinated (MIT) phenol group. The iodination of the phenol groups is carried out by two membrane enzymes of the follicular cells: the double oxidase (DUOX) synthesizes the hydrogen peroxide H2O2 necessary for thyroid peroxidase (TPO).

Due to the spatial conformation of TG, there is a transfer of di or mono iodinated aromatic ring from a donor tyrosine to a close acceptor diiodotyrosine for the 14 tyrosines of the hormonogenic sites. Acceptor iodinated tyrosines are DITs because they are deprotonated due to their 6.5 acid pka facilitating the acceptance reaction leading to the formation of quinol-ether bonds, whereas donor iodinated tyrosines are MITs with a pKa of 8.5^[5]. [m]

At the end of the coupling, the donor tyrosines are left with a dehydroalanine.

Once iodization and coupling have been performed, endocytosis of the colloid to the lysosome occurs. The TG is proteolyzed by cathepsin proteases^[6] [a] and 7 TH are thus released from 14 mono- or di iodinated tyrosines.

The hormone synthesis function of TG is thus particularly linked to its structure. Moreover, research shows that denaturation or a simple modification of its conformation prevents the formation of HT ^[7]^[8]. [k]

[l]

Control

The synthesis of HT from TG is stimulated by thyroid stimulating hormone (TSH) secreted by the pituitary gland, a gland of the brain. When the TSH receptor is activated, glycosylations leading to the mono iodination of tyrosines promote the synthesis of T3^[9]^[10]. b][c] On the other hand, if the amount of hormones is too high, a negative feedback is exerted on this process while a small amount of these hormones exerts a positive feedback.

Iodine tank

The complex and particularly stable structure of TG gives it iodide reservoir properties. Indeed, all iodinated but non-hormonoid tyrosines are useful for iodine storage in the thyroid gland.

Interest in the medical field

Modification of the TG quantity related to the desease

A healthy subject has between 5 and 25 µg of TG per liter of blood. In case of thyroid dysfunction, this level may increase or decrease. For example, it decreases in the case of congenital athyreosis (insufficiency of the thyroid gland) or prior to a miscarriage due to the presence of anti-TG antibodies, but increases in the case of cancer, thyroiditis, inflammation of the thyroid or autoimmune thyroid diseases AITD (Grave's disease, Hashimoto's thyroiditis).

In addition, a decrease in the size or capacity of the thyroid causes a decrease in the synthesis of HT by the TG, and thus a drop in the blood level of T4 and T3, which in turn causes heart disease, brain disease and abnormalities in the development of the fetus.

TG can thus be as much a cause as a consequence of disease.

Use of TG to treat deseases

A classic TSH-stimulated Tg measurement or ultrasensitive Tg measurement allows to control its rate in a more or less sensitive way and therefore to detect a disease like those mentioned above, to ensure the effectiveness of a treatment and the absence of recurrence and to avoid miscarriages. Since serum Tg levels are correlated with the volume of thyroid tissue, we can also estimate the mass of thyroid tissue to detect hyperthyroidism, a disease related to an enlarged thyroid or, conversely, hypothyroidism.

For example, thyroidectomy and a 131I therapy can be performed to cure thyroid cancer with an 80% chance. Following removal and 131I therapy, thyroglobulin is this time produced by malignant thyrocytes. As a result, its blood level is indistinguishable from that of a healthy person.

But in case of recurrence and persistence of cancer, its level can increase again. Thyroglobulin therefore always serves as a tumor marker allowing us to estimate the risk of recurrence (>2ng/ml) or persistence (>1ng/ml) or remission.

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References

↑ Hanson, R. M., Prilusky, J., Renjian, Z., Nakane, T. and Sussman, J. L. (2013), JSmol and the Next-Generation Web-Based Representation of 3D Molecular Structure as Applied to Proteopedia. Isr. J. Chem., 53:207-216. doi:http://dx.doi.org/10.1002/ijch.201300024
↑ Herraez A. Biomolecules in the computer: Jmol to the rescue. Biochem Mol Biol Educ. 2006 Jul;34(4):255-61. doi: 10.1002/bmb.2006.494034042644. PMID:21638687 doi:10.1002/bmb.2006.494034042644
↑ Baas F, van Ommen GJ, Bikker H, Arnberg AC, de Vijlder JJ. The human thyroglobulin gene is over 300 kb long and contains introns of up to 64 kb. Nucleic Acids Res. 1986 Jul 11;14(13):5171-86. doi: 10.1093/nar/14.13.5171. PMID:3016640 doi:http://dx.doi.org/10.1093/nar/14.13.5171
↑ Di Jeso B, Ulianich L, Pacifico F, Leonardi A, Vito P, Consiglio E, Formisano S, Arvan P. Folding of thyroglobulin in the calnexin/calreticulin pathway and its alteration by loss of Ca2+ from the endoplasmic reticulum. Biochem J. 2003 Mar 1;370(Pt 2):449-58. doi: 10.1042/BJ20021257. PMID:12401114 doi:http://dx.doi.org/10.1042/BJ20021257
↑ de Vijlder JJ, den Hartog MT. Anionic iodotyrosine residues are required for iodothyronine synthesis. Eur J Endocrinol. 1998 Feb;138(2):227-31. doi: 10.1530/eje.0.1380227. PMID:9506870 doi:http://dx.doi.org/10.1530/eje.0.1380227
↑ Unknown PubmedID 20198-20204
↑ Rolland M, Montfort MF, Lissitzky S. Efficiency of thyroglobulin as a thyroid hormone-forming protein. Biochim Biophys Acta. 1973 Apr 20;303(2):338-47. doi:, 10.1016/0005-2795(73)90365-6. PMID:4710237 doi:http://dx.doi.org/10.1016/0005-2795(73)90365-6
↑ Maurizis JC, Marriq C, Michelot J, Rolland M, Lissitzky S. Thyroid peroxidase-induced thyroid hormone synthesis in relation to thyroglobulin structure. FEBS Lett. 1979 Jun 1;102(1):82-6. doi: 10.1016/0014-5793(79)80933-3. PMID:456595 doi:http://dx.doi.org/10.1016/0014-5793(79)80933-3
↑ Fassler CA, Dunn JT, Anderson PC, Fox JW, Dunn AD, Hite LA, Moore RC, Kim PS. Thyrotropin alters the utilization of thyroglobulin's hormonogenic sites. J Biol Chem. 1988 Nov 25;263(33):17366-71. PMID:3182849
↑ DI 10.1016/S0021-9258(18)46037-1

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