Role of the type 2 iodothyronine deiodinase (D2) in the control of thyroid hormone signaling

Background

Thyroid hormone signaling is critical for development, growth and metabolic control in vertebrates. Although serum concentration of thyroid hormone is remarkable stable, deiodinases modulate thyroid hormone signaling on a time- and cell-specific fashion by controlling the activation and inactivation of thyroid hormone.

Scope of the review

This review covers the recent advances in D2 biology, a member of the iodothyronine deiodinase family, thioredoxin fold‐containing selenoenzymes that modify thyroid hormone signaling in a time- and cell-specific manner.

Major conclusions

D2-catalyzed T3 production increases thyroid hormone signaling whereas blocking D2 activity or disruption of the Dio2 gene leads to a state of localized hypothyroidism. D2 expression is regulated by different developmental, metabolic or environmental cues such as the hedgehog pathway, the adrenergic- and the TGR5-activated cAMP pathway, by xenobiotic molecules such as flavonols and by stress in the endoplasmic reticulum, which specifically reduces de novo synthesis of D2 via an eIF2a-mediated mechanism. Thus, D2 plays a central role in important physiological processes such as determining T3 content in developing tissues and in the adult brain, and promoting adaptive thermogenesis in brown adipose tissue. Notably, D2 is critical in the T4-mediated negative feed-back at the pituitary and hypothalamic levels, whereby T4 inhibits TSH and TRH expression, respectively. Notably, ubiquitination is a major step in the control of D2 activity, whereby T4 binding to and/or T4 catalysis triggers D2 inactivation by ubiquitination that is mediated by the E3 ubiquitin ligases WSB-1 and/or TEB4. Ubiquitinated D2 can be either targeted to proteasomal degradation or reactivated by deubiquitination, a process that is mediated by the deubiquitinases USP20/33 and is important in adaptive thermogenesis.

General significance

Here we review the recent advances in the understanding of D2 biology focusing on the mechanisms that regulate its expression and their biological significance in metabolically relevant tissues. This article is part of a Special Issue entitled Thyroid hormone signalling.     

Genomic imprinting of the type 3 thyroid hormone deiodinase gene: Regulation and developmental implications

Background

In recent years, findings in a number of animal and human models have ignited renewed interest in the type 3 deiodinase (D3), the main enzyme responsible for the inactivation of thyroid hormones. The induction of D3 in models of illness and injury has raised critical questions about the physiological significance of reduced thyroid hormone availability in those states. Phenotypes in transgenic mice lacking this enzyme also point to important developmental roles for D3. A critical determinant of D3 expression is genomic imprinting, an epigenetic phenomenon that regulates a small number of dosage-critical genes in the mammalian genome. The D3 gene (Dio3) is imprinted and preferentially expressed from one of the alleles in most tissues.

Scope of review

In the context of the physiological significance of D3 and the characteristics and purported origins of genomic imprinting, we review the current knowledge about the epigenetic mechanisms specifying gene dosage in the Dio3 locus.

Major conclusions

Altered Dio3 dosage is detrimental to development, suggesting that the level of thyroid hormone action needs to be exquisitely tailored in a timely fashion to the requirements of particular tissues. An appropriate Dio3 dosage is the result of the coordinated action of certain genomic elements and epigenetic marks in the Dlk1-Dio3 domain.

General significance

The imprinting of Dio3 prompts intriguing questions about why the level of thyroid hormone signaling should be regulated in this rare epigenetic manner, and to what extent altered Dio3 expression due to aberrant imprinting may be implicated in human conditions. This article is part of a Special Issue entitled Thyroid hormone signalling.     

Absence of myocardial thyroid hormone inactivating deiodinase results in restrictive cardiomyopathy in mice

Cardiac injury induces myocardial expression of the thyroid hormone inactivating type 3 deiodinase (D3), which in turn dampens local thyroid hormone signaling. Here, we show that the D3 gene (Dio3) is a tissue-specific imprinted gene in the heart, and thus, heterozygous D3 knockout (HtzD3KO) mice constitute a model of cardiac D3 inactivation in an otherwise systemically euthyroid animal. HtzD3KO newborns have normal hearts but later develop restrictive cardiomyopathy due to cardiac-specific increase in thyroid hormone signaling, including myocardial fibrosis, impaired myocardial contractility, and diastolic dysfunction. In wild-type littermates, treatment with isoproterenol-induced myocardial D3 activity and an increase in the left ventricular volumes, typical of cardiac remodeling and dilatation. Remarkably, isoproterenol-treated HtzD3KO mice experienced a further decrease in left ventricular volumes with worsening of the diastolic dysfunction and the restrictive cardiomyopathy, resulting in congestive heart failure and increased mortality. These findings reveal crucial roles for Dio3 in heart function and remodeling, which may have pathophysiologic implications for human restrictive cardiomyopathy.     

Increased aggression and lack of maternal behavior in Dio3‐deficient mice are associated with abnormalities in oxytocin and vasopressin systems

Thyroid hormones regulate many aspects of brain development and function, and alterations in the levels of thyroid hormone action lead to abnormal anxiety‐ and depression‐like behaviors. A complement of factors in the brain function independently of circulating levels of hormone to strictly controlled local thyroid hormone signaling. A critical factor is the type 3 deiodinase (DIO3), which is located in neurons and protects the brain from excessive thyroid hormone. Here, we examined whether a local increase in brain thyroid hormone action secondary to DIO3 deficiency is of consequence for social behaviors. Although we did not observe alterations in sociability, Dio3?/? mice of both sexes exhibited a significant increase in aggression‐related behaviors and mild deficits in olfactory function. In addition, 85% of Dio3?/? dams manifested no pup‐retrieval behavior and increased aggression toward the newborns. The abnormal social behaviors of Dio3?/? mice were associated with sexually dimorphic alterations in the physiology of oxytocin (OXT) and arginine vasopressin (AVP), 2 neuropeptides with important roles in determining social interactions. These alterations included low adult serum levels of OXT and AVP, and an abnormal expression of Oxt, Avp and their receptors in the neonatal and adult hypothalamus. Our results demonstrate that DIO3 is essential for normal aggression and maternal behaviors, and indicate that abnormal local regulation of thyroid hormone action in the brain may contribute to the social deficits associated with neurodevelopmental disorders.     

Type 3 Deiodinase in Hypoxia: To Cool or to Kill?

Type 3 deiodinase (D3) inactivates thyroid hormones. Simonides et al. (2008) now report that hypoxia-induced D3 activation leads to reduction of 3,5,3'-triiodothyronine (T3) and oxygen consumption, suggesting that D3 activation is a component of cellular responses to hypoxia and supporting the idea of cell-specific regulation of thyroid hormone levels by deiodinases.     

The thyroid hormone-inactivating deiodinase functions as a homodimer

The type 3 deiodinase (D3) inactivates thyroid hormone action by catalyzing tissue-specific inner ring deiodination, predominantly during embryonic development. D3 has gained much attention as a player in the euthyroid sick syndrome, given its robust reactivation during injury and/or illness. Whereas much of the structure biology of the deiodinases is derived from studies with D2, a dimeric endoplasmic reticulum obligatory activating deiodinase, little is known about the holostructure of the plasma membrane resident D3, the deiodinase capable of thyroid hormone inactivation. Here we used fluorescence resonance energy transfer in live cells to demonstrate that D3 exists as homodimer. While D3 homodimerized in its native state, minor heterodimerization was also observed between D3:D1 and D3:D2 in intact cells, the significance of which remains elusive. Incubation with 0.5-1.2 m urea resulted in loss of D3 homodimerization as assessed by bioluminescence resonance energy transfer and a proportional loss of enzyme activity, to a maximum of approximately 50%. Protein modeling using a D2-based scaffold identified potential dimerization surfaces in the transmembrane and globular domains. Truncation of the transmembrane domain (DeltaD3) abrogated dimerization and deiodinase activity except when coexpressed with full-length catalytically inactive deiodinase, thus assembled as DeltaD3:D3 dimer; thus the D3 globular domain also exhibits dimerization surfaces. In conclusion, the inactivating deiodinase D3 exists as homo- or heterodimer in living intact cells, a feature that is critical for their catalytic activities.     

Molecular mechanism of photoperiodic time measurement in the brain of Japanese quail

In most organisms living in temperate zones, reproduction is under photoperiodic control. Although photoperiodic time measurement has been studied in organisms ranging from plants to vertebrates, the underlying molecular mechanism is not well understood. The Japanese quail (Coturnix japonica) represents an excellent model to study this problem because of the rapid and dramatic photoperiodic response of its hypothalamic-pituitary-gonadal axis. Recent investigations of Japanese quail show that long-day-induced type 2 deiodinase (Dio2) expression in the mediobasal hypothalamus (MBH) plays an important role in the photoperiodic gonadal regulation by catalyzing the conversion of the prohormone thyroxine (T(4)) to bioactive 3,5,3'-triiodothyronine (T3). The T3 content in the MBH is approximately 10-fold higher under long than short days and conditions, and the intracerebroventricular infusion of T3 under short days and conditions mimics the photoperiodic gonadal response. While Dio2 generates active T3 from T4 by outer ring deiodination, type 3 deiodinase (Dio3) catalyzes the conversion of both T3 and T4 into inactive forms by inner ring deiodination. In contrast to Dio2 expression, Dio3 expression in the MBH is suppressed under the long-day condition. Photoperiodic changes in the expression of both genes during the photoinduction process occur before the changes in the level of luteinizing hormone (LH) secretion, suggesting that the reciprocal changes in Dio2 and Dio3 expression act as gene switches of the photoperiodic molecular cascade to trigger induction of LH secretion.     

Ubiquitination-induced conformational change within the deiodinase dimer is a switch regulating enzyme activity

Ubiquitination is a critical posttranslational regulator of protein stability and/or subcellular localization. Here we show that ubiquitination can also regulate proteins by transiently inactivating enzymatic function through conformational change in a dimeric enzyme, which can be reversed upon deubiquitination. Our model system is the thyroid hormone-activating type 2 deiodinase (D2), an endoplasmic reticulum-resident type 1 integral membrane enzyme. D2 exists as a homodimer maintained by interacting surfaces at its transmembrane and globular cytosolic domains. The D2 dimer associates with the Hedgehog-inducible ubiquitin ligase WSB-1, the ubiquitin conjugase UBC-7, and VDU-1, a D2-specific deubiquitinase. Upon binding of T4, its natural substrate, D2 is ubiquitinated, which inactivates the enzyme by interfering with D2's globular interacting surfaces that are critical for dimerization and catalytic activity. This state of transient inactivity and change in dimer conformation persists until deubiquitination. The continuous association of D2 with this regulatory protein complex supports rapid cycles of deiodination, conjugation to ubiquitin, and enzyme reactivation by deubiquitination, allowing tight control of thyroid hormone action.     

USP4 inhibits SMAD4 monoubiquitination and promotes activin and BMP signaling

SMAD4 is a common intracellular effector for TGF‐β family cytokines, but the mechanism by which its activity is dynamically regulated is unclear. We demonstrated that ubiquitin‐specific protease (USP) 4 strongly induces activin/BMP signaling by removing the inhibitory monoubiquitination from SMAD4. This modification was triggered by the recruitment of the E3 ligase, SMURF2, to SMAD4 following ligand‐induced regulatory (R)‐SMAD–SMAD4 complex formation. Whereas the interaction of the negative regulator c‐SKI inhibits SMAD4 monoubiquitination, the ligand stimulates the recruitment of SMURF2 to the c‐SKI‐SMAD2 complex and triggers c‐SKI ubiquitination and degradation. Thus, SMURF2 has a role in termination and initiation of TGF‐β family signaling. An increase in monoubiquitinated SMAD4 in USP4‐depleted mouse embryonic stem cells (mESCs) decreased both the BMP‐ and activin‐induced changes in the embryonic stem cell fate. USP4 sustained SMAD4 activity during activin‐ and BMP‐mediated morphogenic events in early zebrafish embryos. Moreover, zebrafish depleted of USP4 exhibited defective cell migration and slower coordinated cell movement known as epiboly, both of which could be rescued by SMAD4. Therefore, USP4 is a critical determinant of SMAD4 activity.     

Kinetics and thiol requirements of iodothyronine 5'-deiodination are tissue-specific in common carp (Cyprinus carpio L.)

Iodothyronine deiodinases determine the biological activity of thyroid hormones. Despite the homology of the catalytic sites of mammalian and teleostean deiodinases, in-vitro requirements for the putative thiol co-substrate dithiothreitol (DTT) vary considerably between vertebrate species. To further our insights in the interactions between the deiodinase protein and its substrates: thyroid hormone and DTT, we measured enzymatic iodothyronine 5′-deiodination, Dio1 and Dio2 mRNA expression, and Dio1 affinity probe binding in liver and kidney preparations from a freshwater teleost, the common carp (Cyprinus carpio L.). Deiodination rates, using reverse T3 (rT3, 3,3′,5′-triiodothyronine) as the substrate, were analysed as a function of the iodothyronine and DTT concentrations. In kidney rT3 5′-deiodinase activity measured at rT3 concentrations up to 10 μM and in the absence of DTT does not saturate appreciably. In the presence of 1 mM DTT, renal rT3 deiodination rates are 20-fold lower. In contrast, rT3 5′-deiodination in liver is potently stimulated by 1 mM DTT. The marked biochemical differences between 5′-deiodination in liver and kidney are not associated with the expression of either Dio1 or Dio2 mRNA since both organs express both deiodinase types. In liver and kidney, DTT stimulates the incorporation of N-bromoacetylated affinity labels in proteins with estimated molecular masses of 57 and 55, and 31 and 28 kDa, respectively. Although primary structures are highly homologous, the biochemistry of carp deiodinases differs markedly from their mammalian counterparts.     

Independence of hyperleptinemia-induced fat disappearance from thyroid hormone

Sustained hyperleptinemia induced in normal rats causes the rapid disappearance of body fat. This is attributed to a marked increase in uncoupled fatty acid oxidation in the white adipocytes, which also occurs in hyperthyroidism. Because hyperleptinemic rats have normal plasma T3 or T4 levels, we tested the possibility of "localized hyperthyroidism" due to increased conversion of T4 to T3 in the adipose tissue. We therefore induced sustained hyperleptinemia in normal rats by intravenous injection of recombinant adenovirus containing the leptin cDNA (AdCMV-leptin) and measured the mRNA and the activity of enzymes involved in T4 metabolism in the disappearing fat. The epididymal fat pad remnants exhibited a decrease in mRNA of deiodinase 1 and a doubling of deiodinase 2 mRNA (p<0.05), but their enzyme activities did not differ from normoleptinemic controls. To determine if thyroid hormone was required for the fat-wasting action of hyperleptinemia, we infused AdCMV-leptin into rats made athyroid by total thyroidectomy or by methimazole therapy. The fat loss in hyperleptinemic athyroid rats was as great as in euthyroid controls. We conclude that the fat-wasting effect of sustained hyperleptinemia does not involve "local hyperthyroidism" in white adipose tissue and does not require thyroid hormone.