Mediator subunit MED1 modulates intranuclear dynamics of the thyroid hormone receptor

Thyroid Hormone Action by Genomic and Nongenomic Molecular Mechanisms

The thyroid hormones, thyroxine (T4) and triiodothyronine (T3), are pivotal in regulating various physiological processes including growth, development, and metabolism. The biological actions of thyroid hormones are primarily initiated by binding to nuclear thyroid hormone receptors (TRs). These receptors, belonging to the superfamily of nuclear receptors, act as ligand-dependent transcription factors. Transcriptional regulation by TRs is mediated by the recruitment of coregulators, governing activation and repression of target genes, thereby modulating cellular responses to thyroid hormones. Beyond this canonical genomic pathway, TH can regulate the expression of genes not directly bound by TRs through cross-talk mechanisms with other transcription factors and signaling pathways. Thyroid hormones can also elicit rapid non-genomic effects, potentially mediated by extranuclear TR proteins or by interactions with membrane receptors such as integrin αvβ3. This non-genomic mode of action adds another layer of complexity to the diverse array of physiological responses orchestrated by thyroid hormones, expanding our understanding of their multifaceted actions.

Nuclear receptor corepressor 1 levels differentially impact the intracellular dynamics of mutant thyroid hormone receptors associated with resistance to thyroid hormone syndrome

Thyroid hormone receptor α1 (TRα1) undergoes nucleocytoplasmic shuttling and mediates gene expression in response to thyroid hormone (T3). In Resistance to Thyroid Hormone Syndrome α (RTHα), certain TRα1 mutants have higher affinity for nuclear corepressor 1 (NCoR1) and may form stable complexes that are not released in the presence of T3. Here, we examined whether NCoR1 modulates intranuclear mobility and nuclear retention of TRα1 or RTHα-associated mutants in transfected human cells, as a way of analyzing critical structural components of TRα1 and to further explore the correlation between mutations in TRα1 and aberrant intracellular trafficking. We found no significant difference in intranuclear mobility, as measured by fluorescence recovery after photobleaching, between TRα1 and select RTHα mutants, irrespective of NCoR1 expression. Nuclear-to-cytoplasmic fluorescence ratios of RTHα mutants, however, varied from TRα1 when NCoR1 was overexpressed, with a significant increase in nuclear retention for A263V and a significant decrease for A263S and R384H. In NCoR1-knockout cells, nuclear retention of A263S, A263V, P389R, A382P, C392X, and F397fs406X was significantly decreased compared to control (wild-type) cells. Luciferase reporter gene transcription mediated by TRα1 was significantly repressed by both NCoR1 overexpression and NCoR1 knockout. Most RTHα mutants showed minimal induction regardless of NCoR1 levels, but T3-mediated transcriptional activity was decreased for R384C and F397fs406X when NCoR1 was overexpressed, and also decreased for N359Y in NCoR1-knockout cells. Our results suggest a complex interaction between NCoR1 and RTHα mutants characterized by aberrant intracellular localization patterns and transcriptional activity that potentially arise from variable repressor complex stability, and may provide insight into RTHα pathogenesis on a molecular and cellular level.

Mediator subunit MED1 differentially modulates mutant thyroid hormone receptor intracellular dynamics in Resistance to Thyroid Hormone syndrome

Thyroid hormone receptor (TR) controls the expression of thyroid hormone (T3)-responsive genes, while undergoing rapid nucleocytoplasmic shuttling. In Resistance to Thyroid Hormone syndrome (RTH), mutant TR fails to activate T3-dependent transcription. Previously, we showed that Mediator subunit 1 (MED1) plays a role in TR nuclear retention. Here, we investigated MED1's effect on RTH mutants using nucleocytoplasmic scoring and fluorescence recovery after photobleaching in transfected cells. MED1 overexpression and knockout did not change the nucleocytoplasmic distribution or intranuclear mobility of C392X and P398R TRα1 at physiological T3 levels. At elevated T3 levels, however, overexpression increased P398R's nuclear retention and MED1 knockout decreased P398R's and A263V's intranuclear mobility, while not impacting C392X. Although A263V TRα1-transfected cells had a high percentage of aggregates, MED1 rescued A263V's impaired intranuclear mobility, suggesting that MED1 ameliorates nonfunctional aggregates. Results correlate with clinical severity, suggesting that altered interaction between MED1 and TRα1 mutants contributes to RTH pathology.

Cross-Talk between the Cytokine IL-37 and Thyroid Hormones in Modulating Chronic Inflammation Associated with Target Organ Damage in Age-Related Metabolic and Vascular Conditions

Chronic inflammation is considered to be the main mechanism contributing to the development of age-related metabolic and vascular conditions. The phases of chronic inflammation that mediate the progression of target organ damage in these conditions are poorly known, however. In particular, there is a paucity of data on the link between chronic inflammation and metabolic disorders. Based on some of our own results and recent developments in our understanding of age-related inflammation as a whole-body response, we discuss the hypothesis that cross-talk between the cytokine IL-37 and thyroid hormones could be the key regulatory mechanism that justifies the metabolic effects of chronic tissue-related inflammation. The cytokine IL-37 is emerging as a strong natural suppressor of the chronic innate immune response. The effect of this cytokine has been identified in reversing metabolic costs of chronic inflammation. Thyroid hormones are known to regulate energy metabolism. There is a close link between thyroid function and inflammation in elderly individuals. Nonlinear associations between IL-37 and thyroid hormones, considered within the wider clinical context, can improve our understanding of the phases of chronic inflammation that are associated with target organ damage in age-related metabolic and vascular conditions.

HOXA5 induces M2 macrophage polarization to attenuate carotid atherosclerosis by activating MED1

Macrophage polarization is of great importance in the formation of atherosclerotic plaque. Homeobox A5 (HOXA5), one of the homeobox transcription factors, has been revealed to be closely associated with macrophage phenotype switching. This study aims to investigate the role of HOXA5 in carotid atherosclerosis (CAS). Herein, the role of HOXA5 was explored in polarized RAW264.7 macrophages in vitro and ApoE^-/- mice in vivo. Interestingly, compared with that in M0 macrophages, both the mRNA and protein expression levels of HOXA5 were decreased in lipopolysaccharide (LPS)/interferon (IFN)-γ-induced M1 macrophages, while increased in IL-4-induced M2 macrophages. In addition, in the presence of IL-4, HOXA5-overexpressing RAW264.7 cells preferred to polarizing toward M2 phenotypes. Furthermore, we found that HOXA5 bound to the promoter region and activated the expression of mediator subunit 1 (MED1), a gene known to regulate macrophage differentiation. Knocking MED1 down inhibited HOXA5-enhanced M2 macrophage polarization. In vivo, the CAS model was induced in ApoE^-/- mouse fed with a Western-type diet and placed a perivascular carotid collar. Decreased mRNA and protein expressions of HOXA5 were observed in carotid arteries of CAS mice. Forced overexpression of HOXA5 reduced intimal hyperplasia and lipid accumulation in carotid vessels, and it also promoted the polarization of macrophages to M2 subtypes. The expression of MED1 was decreased in atherosclerotic carotid vessels, while HOXA5 overexpression restored its change. Collectively, HOXA5 in carotid arteries is involved in the macrophage M1/M2 switching in atherosclerotic plaque, which may be associated with its transcriptional regulation of MED1.

Getting there: Thyroid hormone receptor intracellular trafficking

A year ago, when I first contemplated writing this article, my intent was to provide a detailed review of the contributions of the diverse community of talented scientists in my lab to the nuclear receptor research field. In the throes of a deadly pandemic, political turmoil, and Black Lives Matter, however, I found myself compelled to tell a more personal story. While I will still cover milestones in our understanding of the intracellular trafficking of the thyroid hormone receptor, now these will be set against the backdrop of my path as a woman in STEM and on being intentionally inclusive. By sharing reflections on my journey, I hope to encourage young investigators to persist in their pursuit of a career in science.