Heterozygosity of genetically encoded misfolded mutant thyroglobulin (TG, the thyroid hormone protein precursor) occurs with a frequency estimated at 1-in-217 people worldwide, resulting in subclinical hypothyroidism that largely escapes medical detection. However, patients carrying biallelic TG mutation, when untreated, are frankly hypothyroid unless and until they develop a massive goiter. To date, TG is the only proven endogenous precursor protein for thyroid hormone synthesis in vertebrates. Our objective was to understand how homozygous expression of mutant TG protein that cannot undergo secretion to the iodination site in the thyroid follicle lumen can be compatible with patients or animal models ultimately achieving normal/near-normal circulating T4 and T3 levels. Notably, in both monoallelic and biallelic disease, dead thyrocytes have been reported in the lumen of thyroid follicles.
Methods:
We recently engineered mice with homozygous Tg-KO, making it possible to study circulating T4 and T3 in the complete absence of TG protein expression. We also employed immunoblotting methods to test for the presence of thyroidal T4-containing and T3-containing protein.
Results:
We found that, concomitant with goiter growth, animals completely lacking TG (like patients or animals with biallelic TG defect) are able to eventually normalize circulating T4 levels when their goiter has sufficiently enlarged, while maintaining serum T3 at ∼two-thirds normal levels throughout life. Very little T3-containing protein is synthesized in the thyroid glands of Tg-KO mice; however, T4-containing protein is synthesized on the ghosts of dead thyrocytes, with T3 generated from circulating T4 deiodination. Albeit inefficient, thyroidal T4-containing protein content is not appreciably different in the presence of homozygous mutant TG or in the complete absence of TG.
Conclusions:
Our data suggest that in biallelic TG mutation, thyroid stimulating hormone (TSH)-driven iodination underlies inefficient T4 formation derived from the iodoproteome of dead thyrocytes. In the presence of homozygous mutant TG or in the complete absence of TG, normalizing circulating T4 requires massive goiter growth to generate sufficient cells to sustain this inefficient hormonogenesis mechanism.
BeydounMA, BeydounHA, Kitner-TrioloMH, et al.Thyroid hormones are associated with cognitive function: Moderation by sex, race, and depressive symptoms. J Clin Endocrinol Metab2013;98(8):3470–3481.
5.
KrassasGE, PoppeK, GlinoerD. Thyroid function and human reproductive health. Endocr Rev2010;31(5):702–755.
6.
CitterioCE, TargovnikHM, ArvanP. The role of thyroglobulin in thyroid hormonogenesis. Nat Rev Endocrinol2019;15(6):323–338; doi: 10.1038/s41574-019-0184-8
7.
StejskalovaC, ArrigoniF, AlbanesiR, et al.A conserved acidic residue drives thyroxine synthesis within thyroglobulin and other protein precursors. J Biol Chem2025;301(1):108026.
8.
HolzerG, MorishitaY, FiniJB, et al.Thyroglobulin represents a novel molecular architecture of vertebrates. J Biol Chem2016;291(32):16553–16566; doi: 10.1074/jbc.M116.719047
9.
CosciaF, Taler-VercicA, ChangVT, et al.The structure of human thyroglobulin. Nature2020;578(7796):627–630; doi: 10.1038/s41586-020-1995-4
10.
AdaixoR, SteinerEM, RighettoRD, et al.Cryo-EM structure of native human thyroglobulin. Nat Commun2022;13(1):61; doi: 10.1038/s41467-021-27693-8
11.
KimK, KopylovM, BobeD, et al.The structure of natively iodinated bovine thyroglobulin. Acta Crystallogr D Struct Biol2021;77(Pt 11):1451–1459; doi: 10.1107/S2059798321010056
12.
MarechalN, SerranoBP, ZhangX, et al.Formation of thyroid hormone revealed by a cryo-EM structure of native bovine thyroglobulin. Nat Commun2022;13(1):2380; doi: 10.1038/s41467-022-30082-4
13.
Di JesoB, ArvanP. Thyroglobulin from molecular and cellular biology to clinical endocrinology. Endocr Rev2016;37(1):2–36; doi: 10.1210/er.2015-1090
14.
ZhangX, YoungC, MorishitaY, et al.Defective thyroglobulin: Cell biology of disease. Int J Mol Sci2022;23(21):13605; doi: 10.3390/ijms232113605
15.
ZhangX, KelloggAP, CitterioCE, et al.Thyroid hormone synthesis continues despite biallelic thyroglobulin mutation with cell death. JCI Insight2021;6(11):e148496; doi: 10.1172/jci.insight.148496
16.
HishinumaA, TakamatsuJ, OhyamaY, et al.Two novel cysteine substitutions (C1263R and C1995S) of thyroglobulin cause a defect in intracellular transport of thyroglobulin in patients with congenital goiter and the variant type of adenomatous goiter. J Clin Endo Metab1999;84(4):1438–1444.
17.
KimPS, KwonO-Y, ArvanP. An endoplasmic reticulum storage disease causing congenital goiter with hypothyroidism. J Cell Biol1996;133(3):517–527.
18.
KimPS, HossainSA, ParkYN, et al.A single amino acid change in the acetylcholinesterase-like domain of thyroglobulin causes congenital goiter with hypothyroidism in the cog/cog mouse: A model of human endoplasmic reticulum storage diseases. Proceedings of the National Academy of Sciences of the United States of America1998;95(17):9909–9913.
19.
HishinumaA, FurudateS, Oh-IshiM, et al.A novel missense mutation (G2320R) in thyroglobulin causes hypothyroidism in rdw rats. Endocrinology2000;141(11):4050–4055.
20.
AtsugiT, YokouchiM, HiranoT, et al.Holocrine secretion occurs outside the TightJunction barrier in multicellular glands: Lessons from claudin-1-deficient mice. J Invest Dermatol2020;140(2):298–308.e5.
21.
ColeW, WomackN, EllettW. The production of hyperplasia of the thyroid gland by chemical means: With special reference to purine bases and their derivatives. Arch Surg1931;22(6):926–935; doi: 10.1001/archsurg.1931.01160060054003
22.
YoungC, ZhangX, WangX, et al.Stimulated thyroid hormone synthesis machinery drives thyrocyte cell death independent of ER stress. J Clin Invest2025;135(24):e187044; doi: 10.1172/JCI187044
23.
ZhangX, MalikB, YoungC, et al.Maintaining the thyroid gland in mutant thyroglobulin-induced hypothyroidism requires thyroid cell proliferation that must continue in adulthood. J Biol Chem2022;298(7):102066; doi: 10.1016/j.jbc.2022.102066
24.
ZhangX, YoungC, LiaoXH, et al.Perturbation of endoplasmic reticulum proteostasis triggers tissue injury in the thyroid gland. JCI Insight2023;8(12):e169937; doi: 10.1172/jci.insight.169937
25.
PohlenzJ, MaqueemA, CuaK, et al.Improved radioimmunoassay for measurement of mouse thyrotropin in serum: Strain differences in thyrotropin concentration and thyrotroph sensitivity to thyroid hormone. Thyroid1999;9(12):1265–1271.
26.
FerraraAM, LiaoXH, Gil-IbanezP, et al.Changes in thyroid status during perinatal development of MCT8-deficient male mice. Endocrinology2013;154(7):2533–2541; doi: 10.1210/en.2012-2031
27.
Curcio-MorelliC, GerebenB, ZavackiAM, et al.In vivo dimerization of types 1, 2, and 3 iodothyronine selenodeiodinases. Endocrinology2003;144(3):937–946; doi: 10.1210/en.2002-220960
28.
CitterioCE, MorishitaY, DakkaN, et al.Relationship between the dimerization of thyroglobulin and its ability to form triiodothyronine. J Biol Chem2018;293(13):4860–4869; doi: 10.1074/jbc.RA118.001786
29.
MorishitaY, KabilO, YoungKZ, et al.Thyrocyte cell survival and adaptation to chronic endoplasmic reticulum stress due to misfolded thyroglobulin. J Biol Chem2020;295(20):6876–6887; doi: 10.1074/jbc.RA120.012656
30.
CitterioCE, KimK, RajeshB, et al.Structural features of thyroglobulin linked to protein trafficking. Protein Sci2023;32(11):e4784; doi: 10.1002/pro.4784
31.
WangY, ShimizuH, XiangY-Y, et al.XB130 deficiency causes congenital hypothyroidism in mice due to disorganized apical membrane structure and function of thyrocytes. Thyroid2021;31(11):1650–1661.
32.
AdkisonLR, TaylorS, BeamerWG. Mutant gene-induced disorders of structure, function and thyroglobulin synthesis in congenital goitre (cog/cog) in mice. J Endocrinol1990;126(1):51–58.
33.
DunnJT, DunnAD. The importance of thyroglobulin structure for thyroid hormone biosynthesis. Biochimie1999;81(5):505–509.
34.
CitterioCE, Morales-RodriguezB, LiaoX-H, et al.A genetically-engineered thyroid gland built for selective triiodothyronine secretion. Int J Mol Sci2025;26(15):7166.
35.
DanielB, DeCosterMA. Quantification of sPLA2-induced early and late apoptosis changes in neuronal cell cultures using combined TUNEL and DAPI staining. Brain Res Brain Res Protoc2004;13(3):144–150.
36.
GentileF, SalvatoreG. Preferential sites of proteolytic cleavage of bovine, human, and rat thyroglobulin. The use of limited proteolysis to detect solvent exposed regions of the primary structure. Eur J Biochem1993;218(2):603–621.
37.
RoussetB, SelmiS, BornetH, et al.Thyroid hormone residues are released from thyroglobulin with only limited alteration of the thyroglobulin structure. J Biol Chem1989;264(21):12620–12626.
38.
Arrojo E DrigoR, FonsecaTL, Werneck-de-CastroJPS, et al.Role of the type 2 iodothyronine deiodinase (D2) in the control of thyroid hormone signaling. Biochim Biophys Acta2013;1830(7):3956–3964.
39.
EttlesonMD, PrietoWH, RussoPST, et al.Serum thyrotropin and triiodothyronine levels in levothyroxine-treated patients. J Clin Endocrinol Metab2023;108(6):e258–e266.
40.
GerebenB, GoncalvesC, HarneyJW, et al.Selective proteolysis of human type 2 deiodinase: A novel ubiquitin-proteasomal mediated mechanism for regulation of hormone activation. Mol Endocrinol2000;14(11):1697–1708.
41.
HishinumaA, FukataS, NishiyamaS, et al.Haplotype analysis reveals founder effects of thyroglobulin gene mutations C1058R and C1977S in Japan. J Clin Endocrinol Metab2006;91(8):3100–3104.
42.
NicholasAK, SerraEG, CangulH, et al.Comprehensive screening of eight known causative genes in congenital hypothyroidism with gland-in-situ. J Clin Endocrinol Metab2016;101(12):4521–4531; doi: 10.1210/jc.2016-1879
43.
SiffoS, AdroverE, CitterioCE, et al.Molecular analysis of thyroglobulin mutations found in patients with goiter and hypothyroidism. Mol Cell Endocrinol2018;473:1–16; doi: 10.1016/j.mce.2017.12.009
44.
MatsuyamaM, SawadaH, InoueS, et al.Goiter in a 6-year-old patient with novel thyroglobulin gene variant (Gly145Glu) causing intracellular thyroglobulin transport disorder: Correlation between goiter size and the free T3 to free T4 ratio. Clin Pediatr Endocrinol2022;31(3):185–191.
45.
LissitzkyS, BismuthJ, CodaccioniJL, et al.Congenital goiter with iodoalbumin replacing thyroglobulin and defect of deiodination of iodotyrosines. Serum origin of the thyroid iodoalbumin. J Clin Endo Metab1968;28(12):1797–1806.
46.
de VijlderJJ, VeenboerGJ, van DijkJE. Thyroid albumin originates from blood. Endocrinology1992;131(2):578–584.
47.
GireV, KostrouchZ, Bernier-ValentinF, et al.Endocytosis of albumin and thyroglobulin at the basolateral membrane of thyrocytes organized in follicles. Endocrinology1996;137(2):522–532.
48.
MoritaR. [Iodine metabolism in chronic thyroiditis. 2. Studies on the iodinated albumin-like proteins in the serum and the thyroid tissue in chronic thyroiditis]. Nihon Naibunpi Gakkai Zasshi1971;46(10):1097–1108.
49.
SavoieJC, MassinJP, SavoieF. Studies on mono- and diiodohistidine. II. Congenital goitrous hypothyroidism with thyroglobulin defect and iodohistidine-rich iodoalbumin production. J Clin Invest1973;52(1):116–125.
50.
O’MaraBA, DittrichW, LauterioTJ, et al.Pretranslational regulation of type I 5′-deiodinase by thyroid hormones and in fasted and diabetic rats. Endocrinology1993;133(4):1715–1723.
