Central : -
Thyroglobulin is synthesized in the
rough endoplasmic reticulum and follows the
secretory pathway to enter the colloid in the lumen of the
thyroid follicle by
exocytosis. - Meanwhile, a
sodium-iodide (Na/I) symporter pumps iodide (I−)
actively into the cell, which previously has crossed the
endothelium by largely unknown mechanisms. - This iodide enters the follicular lumen from the cytoplasm by the transporter
pendrin, in a purportedly
passive manner. - In the colloid, iodide (I−) is
oxidized to iodine (I0) by an enzyme called
thyroid peroxidase. - Iodine (I0) is very reactive and iodinates the thyroglobulin at
tyrosyl residues in its protein chain (in total containing approximately 120 tyrosyl residues). - In
conjugation, adjacent tyrosyl residues are paired together. - Thyroglobulin re-enters the follicular cell by
endocytosis. -
Proteolysis by various
proteases liberates thyroxine and
triiodothyronine molecules - Efflux of thyroxine and triiodothyronine from follicular cells, which appears to be largely through
monocarboxylate transporter 8 (MCT 8) and
10, The steps in this process are as follows:
Sodium is cotransported with iodide from the basolateral side of the membrane into the cell, and then concentrated in the thyroid follicles to about thirty times its concentration in the blood. • I− is moved across the apical membrane into the colloid of the follicle by
pendrin. Hydrogen peroxide is also introduced into the follicle by the action of DUX (Dual Oxidase). • Iodide is non-reactive, and the reactive I2 species is required for the next step. Thyroid peroxidase (TPO) reduces hydrogen peroxide to water by transferring one electron from two I− atoms that react to form I2. • Iodine (I2) is converted into
HOI, by hydration with water. Both I2 and HOI iodinate specific tyrosyl residues of the thyroglobulin within the colloid to form
3-monoiodityrosyl (MIT-yl) and
3,5-diiodityrosyl (DIT-yl) residues—introducting iodine atoms at one or both locations
ortho to the hydroxyls of tyrosine. The thyroglobulin was synthesised in the ER of the follicular cell and secreted into the colloid. • TPO also converts tyrosyl, MIT-yl, and DIT-yl residues into their free radical forms. These forms attack other MIT-yl and DIT-yl residues. When a DIT-yl radical attacks a DIT, T4-yl (peptidic T4) is formed. When a MIT-yl radical attacks a DIT, T3-yl is formed. Other reactions are possible, but do not form physiologically active products. • Iodinated thyroglobulin binds
megalin for endocytosis back into the cell. • TSH released from the anterior pituitary ( the adenohypophysis) binds the
TSH receptor (a Gs protein-coupled receptor) on the basolateral membrane of the cell and stimulates the endocytosis of the colloid. • The endocytosed vesicles fuse with the lysosomes of the follicular cell. The lysosomal enzymes cleave any MIT, DIT, T3, T4 as well as the inactive analogues from the iodinated thyroglobulin. • The thyroid hormones cross the follicular cell membrane towards the blood vessels by an unknown mechanism. but recent studies indicate that
monocarboxylate transporter 8 (MCT 8) and
10 play major roles in the efflux of the thyroid hormones from thyroid cells. Thyroglobulin (Tg) is a 660
kDa, dimeric
protein produced by the follicular cells of the thyroid and used entirely within the thyroid gland. Thyroxine is produced by attaching iodine atoms to the ring structures of this protein's
tyrosine residues; thyroxine (T4) contains four iodine atoms, while triiodothyronine (T3), otherwise identical to T4, has one less iodine atom per molecule. The thyroglobulin protein accounts for approximately half of the protein content of the thyroid gland. Each thyroglobulin molecule contains approximately 100–120 tyrosine residues, a small number (3 and T4 are the result. Therefore, each thyroglobulin protein molecule ultimately yields very small amounts of thyroid hormone (experimentally observed to be on the order of 5–6 molecules of either T4 or T3 per original molecule of thyroglobulin).
Peripheral Thyroxine is believed to be a
prohormone and a reservoir for the most active and main thyroid hormone, T3. T4 is converted as required in the tissues by
iodothyronine deiodinase. Deficiency of deiodinase can mimic hypothyroidism due to iodine deficiency. T3 is more active than T4, though it is present in less quantity than T4.
Initiation of production in fetuses Thyrotropin-releasing hormone (TRH) is released from hypothalamus by 6–8
gestational weeks, and
thyroid-stimulating hormone (TSH) secretion from the fetal pituitary gland is evident by 12 gestational weeks; fetal production of thyroxine (T4) reaches a clinically significant level at 18–20 weeks. Fetal
triiodothyronine (T3) remains low (less than 15 ng/dL) until 30 weeks of gestation, and increases to 50 ng/dL at term.
Iodine deficiency Among humans with dietary
iodine deficiency, the thyroid will not be able to make thyroid hormones. The lack of thyroid hormones will lead to decreased
negative feedback on the pituitary gland, leading to increased production of
thyroid-stimulating hormone, which causes the thyroid to enlarge in a medical condition called
endemic colloid goitre. This has the effect of increasing the thyroid's ability to trap more iodide, compensating for the iodine deficiency and allowing it to produce adequate amounts of thyroid hormone. ==Circulation and transport==