Michelle A. Mulcahey

TET1 is a DNA-binding protein that modulates DNA methylation and gene transcription via hydroxylation of 5-methylcytosine

TET1 is a DNA-binding protein that modulates DNA methylation and gene transcription via hydroxylation of 5-methylcytosine

Type 2 Deiodinase Expression Is Induced by Peroxisomal Proliferator-Activated Receptor-γ Agonists in Skeletal Myocytes

The thyroid hormone activating type 2 deiodinase (D2) is known to play a role in brown adipose tissue-mediated adaptive thermogenesis in rodents, but the finding of D2 in skeletal muscle raises the possibility of a broader metabolic role. In the current study, we examined the regulation of the D2 pathway in primary skeletal muscle myoblasts taken from both humans and mice. We found that pioglitazone treatment led to a 1.6- to 1.9-fold increase in primary human skeletal myocyte D2 activity; this effect was seen with other peroxisomal proliferator-activated receptor-gamma agonists. D2 activity in primary murine skeletal myotubes increased 2.8-fold in response to 5 microM pioglitazone and 1.6-fold in response to 5 nM insulin and increased in a dose-dependent manner in response to lithocholic acid (maximum response at 25 microM was approximately 3.8-fold). We compared Akt phosphorylation in primary myotubes derived from wild-type and D2 knockout (D2KO) mice: phospho-Akt was reduced by 50% in the D2KO muscle after 1 nM insulin exposure. Expression of T(3)-responsive muscle genes via quantitative RT-PCR suggests that D2KO cells have decreased thyroid hormone signaling, which could contribute to the abnormalities in insulin signaling. D2 activity in skeletal muscle fragments from both murine and human sources was low, on the order of about 0.01 fmol/min . mg of muscle protein. The phenotypic changes seen with D2KO cells support a metabolic role for D2 in muscle, hinting at a D2-mediated linkage between thyroid hormone and insulin signaling, but the low activity calls into question whether skeletal muscle D2 is a major source of plasma T(3).

Type 2 Iodothyronine Deiodinase Levels Are Higher in Slow-Twitch than Fast-Twitch Mouse Skeletal Muscle and Are Increased in Hypothyroidism

Because of its large mass, relatively high metabolic activity and responsiveness to thyroid hormone, skeletal muscle contributes significantly to energy expenditure. Despite the presence of mRNA encoding the type 2 iodothyronine-deiodinase (D2), an enzyme that activates T(4) to T3, very low or undetectable activity has been reported in muscle homogenates of adult humans and mice. With a modified D2 assay, using microsomal protein, overnight incubation and protein from D2 knockout mouse muscle as a tissue-specific blank, we examined slow- and fast-twitch mouse skeletal muscles for D2 activity and its response to physiological stimuli. D2 activity was detectable in all hind limb muscles of 8- to 12-wk old C57/BL6 mice. Interestingly, it was higher in the slow-twitch soleus than in fast-twitch muscles (0.40 ± 0.06 vs. 0.076 ± 0.01 fmol/min · mg microsomal protein, respectively, P < 0.001). These levels are greater than those previously reported. Hypothyroidism caused a 40% (P < 0.01) and 300% (P < 0.001) increase in D2 activity after 4 and 8 wk treatment with antithyroid drugs, respectively, with no changes in D2 mRNA. Neither D2 mRNA nor activity increased after an overnight 4 C exposure despite a 10-fold increase in D2 activity in brown adipose tissue in the same mice. The magnitude of the activity, the fiber specificity, and the robust posttranslational response to hypothyroidism argue for a more important role for D2-generated T(3) in skeletal muscle physiology than previously assumed.

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.

Consumptive Hypothyroidism Resulting from Hepatic Vascular Tumors in an Athyreotic Adult

CONTEXT Consumptive hypothyroidism is a rare syndrome resulting from increased catabolism of T(4) and T(3) by increased type 3 iodothyronine deiodinase (D3) activity. Consumptive hypothyroidism has primarily been described as a paraneoplastic syndrome in infants as well as in two adults with D3-expressing tumors. OBJECTIVE The aim of the study was to report the third case of consumptive hypothyroidism in an adult and the first in an athyreotic patient. DESIGN, SETTING, AND PATIENT We present a 38-yr-old athyreotic female who was euthyroid on a stable therapeutic dose of thyroid hormone for many years and then developed marked hyperthyrotropinemia, coincident with the discovery of large D3-expressing hepatic vascular tumors. The patient also had low serum T(3) and elevated serum rT(3). Hyperthyrotropinemia transiently worsened after surgical resection of the vascular tumors and then persisted for 3 wk after the operation, despite further increases in levothyroxine therapy. INTERVENTION The patients vascular tumor and adjacent normal liver parenchyma were probed with a polyclonal antibody directed against D3. MAIN OUTCOME MEASURES AND RESULTS D3 immunostaining of the patients vascular tumor was positive, with no significant immunoreactivity in the adjacent normal hepatic tissue. CONCLUSIONS This is the third case report of consumptive hypothyroidism in an adult and the first in an athyreotic individual. This case demonstrates that hyperthyrotropinemia may persist after partial liver resection, possibly from the hepatic resection itself.

Effect of epinephrine deficiency on cold tolerance and on brown adipose tissue.

Catecholamines are involved in thermogenesis. We investigated the specific role of epinephrine in regulation of temperature homeostasis in mice. We subjected adult wildtype (WT) and phenylethanolamine N-methyl transferase knock out mice (Pnmt(-/-)) lacking epinephrine to cold for 24h. Body temperature and thyroid hormone levels were not different between WT and Pnmt(-/-) mice. Although temperature was normal in Pnmt(-/-) mice, the brown fat response to cold was abnormal with no increase in Ucp-1 or Pgc-1alpha mRNA levels (but with an exaggerated cold-induced lipid loss from the tissue). Our results show that epinephrine may have a role in brown fat mitochondrial uncoupling through regulation of Ucp-1 and Pgc-1alpha, although this is not required to maintain a normal temperature during acute cold exposure. We conclude that epinephrine may have an important role in induction of Ucp-1 and Pgc-1alpha gene expression during cold stress.

Knockdown of the Type 3 Iodothyronine Deiodinase (D3) Interacting Protein Peroxiredoxin 3 Decreases D3-Mediated Deiodination in Intact Cells

The type 3 iodothyronine deiodinase (D3) is the primary deiodinase that inactivates thyroid hormone. Immunoprecipitation of D3, followed by fluorescent two-dimensional difference gel electrophoresis and mass spectrometry, identified peroxiredoxin 3 (Prx3) as a D3-associated protein. This interaction was confirmed using reverse coimmunoprecipitation, in which pull-down of Prx3 resulted in D3 isolation, and by fluorescence resonance energy transfer between cyan fluorescent protein-D3 and yellow fluorescent protein-Prx3. Prx3 overexpression did not change D3 activity in transfected HEK 293 cells; however, Prx3 knockdown resulted in a 50% decrease in D3-mediated whole-cell deiodination. Notably, D3 activity of cell lysates with dithiothreitol as an exogenous reducing factor and D3 protein levels were not decreased with Prx3 knockdown, indicating that the observed reduction in whole-cell deiodination was not simply due to a decrease in D3 enzyme levels. Prx3 knockdown did not change D3s affinity for T3 because saturation of D3-mediated whole-cell deiodination occurred between 20 and 200 nm T3 both with and without Prx3. Furthermore, the decrease in D3 activity in whole cells was not attributable to nonspecific oxidative stress because pretreatment with the antioxidant N-acetyl cysteine did not reverse the effects of Prx3 knockdown. Thioredoxin, the cofactor needed for Prx3 regeneration, supported D3 microsomal activity; however, Prx3 knockdown did not change D3 activity in this system. In conclusion, knockdown of Prx3 decreases D3 activity in whole cells, whereas absolute levels of D3 are unchanged, consistent with Prx3 playing a rate-limiting role in the regeneration of the D3 enzyme.