Project description:In the neonatal liver, a peak of type 2 deiodinase (D2) activity accelerates local T3 production and the expression of thyroid hormone (TH)-responsive genes. Here we show that this acute increase in T3 signaling permanently modifies hepatic gene expression. Liver-specific Dio2 inactivation (Alb-D2KO) transiently increased H3K9me3 levels during post-natal days 1-5 (P1-P5) in discrete chromatin areas, and methylation of 1,508 DNA sites (H-sites) that remained in the adult mouse liver. These sites were associated with 1,551 areas of reduced chromatin accessibility (RCA; Atac-seq) within core promoters and 2,426 within intergenic regions, with reduction in the expression of 1,525 genes (RNA-seq). There was strong correlation between H-sites and RCA sites (r=0.85; p<0.0002), suggesting a cause-effect relationship. The analysis of chromosome conformation capture (Hi-C) data revealed a set of 57 repressed genes that have a promoter RCA in close contact with an intergenic RCA ~300 Kbp apart, including Foxa2 that plays an important role during development. Thus, the post-natal surge in hepatic D2 activity and TH-signaling prevents discrete DNA methylation and modifies the transcriptome of the adult mouse. This explains how the systemic T3 hormone acts locally during development to define future chromatin accessibility and expression of critically relevant hepatic genes.

Project description:In the neonatal liver, a peak of type 2 deiodinase (D2) activity accelerates local T3 production and the expression of thyroid hormone (TH)-responsive genes. Here we show that this acute increase in T3 signaling permanently modifies hepatic gene expression. Liver-specific Dio2 inactivation (Alb-D2KO) transiently increased H3K9me3 levels during post-natal days 1-5 (P1-P5) in discrete chromatin areas, and methylation of 1,508 DNA sites (H-sites) that remained in the adult mouse liver. These sites were associated with 1,551 areas of reduced chromatin accessibility (RCA; Atac-seq) within core promoters and 2,426 within intergenic regions, with reduction in the expression of 1,525 genes (RNA-seq). There was strong correlation between H-sites and RCA sites (r=0.85; p<0.0002), suggesting a cause-effect relationship. The analysis of chromosome conformation capture (Hi-C) data revealed a set of 57 repressed genes that have a promoter RCA in close contact with an intergenic RCA ~300 Kbp apart, including Foxa2 that plays an important role during development. Thus, the post-natal surge in hepatic D2 activity and TH-signaling prevents discrete DNA methylation and modifies the transcriptome of the adult mouse. This explains how the systemic T3 hormone acts locally during development to define future chromatin accessibility and expression of critically relevant hepatic genes.

Project description:In the neonatal liver, a peak of type 2 deiodinase (D2) activity accelerates local T3 production and the expression of thyroid hormone (TH)-responsive genes. Here we show that this acute increase in T3 signaling permanently modifies hepatic gene expression. Liver-specific Dio2 inactivation (Alb-D2KO) transiently increased H3K9me3 levels during post-natal days 1-5 (P1-P5) in discrete chromatin areas, and methylation of 1,508 DNA sites (H-sites) that remained in the adult mouse liver. These sites were associated with 1,551 areas of reduced chromatin accessibility (RCA; Atac-seq) within core promoters and 2,426 within intergenic regions, with reduction in the expression of 1,525 genes (RNA-seq). There was strong correlation between H-sites and RCA sites (r=0.85; p<0.0002), suggesting a cause-effect relationship. The analysis of chromosome conformation capture (Hi-C) data revealed a set of 57 repressed genes that have a promoter RCA in close contact with an intergenic RCA ~300 Kbp apart, including Foxa2 that plays an important role during development. Thus, the post-natal surge in hepatic D2 activity and TH-signaling prevents discrete DNA methylation and modifies the transcriptome of the adult mouse. This explains how the systemic T3 hormone acts locally during development to define future chromatin accessibility and expression of critically relevant hepatic genes.

Project description:The monocarboxylate transporter 8 (Mct8) protein is a primary T4 and T3 (TH) transporter. Mutations of the MCT8-encoding, SLC16A2 gene alters thyroid function and thyroid hormone metabolism, and severely impairs neurodevelopment (Allan-Herndon-Dudley syndrome, AHDS). Mct8-deficient mice manifest thyroid alterations but lack neurological signs. It is thought that Mct8 deficiency in mice is compensated by T4 transport through the Slco1c1-encoded organic anion transporter polypeptide 1c1 (Oatp1c1). This allows local brain generation of sufficient T3 by the Dio2-encoded type 2 deiodinase (D2). The Slc16a2/Slco1c1 (MO) and Slc16a2/Dio2 (MD) double knock out mice lacking T4 and T3 transport, or T3 transport and T4 deiodination, would be more approriate models of AHDS. The goal of this work was to compare the cerebral hypothyroidism of systemic hypothyroidism (SH) caused by thyroid gland blockade with that present in the double KOs.

Project description:The role of deiodinase-mediated TH effects in early vertebrate development is only partially understood. Therefore, we investigated the role of deiodinases during early development of zebrafish until 96 hours post fertilization at the level of the transcriptome, biochemistry, morphology and physiology using morpholino (MO) knockdown. Knockdown of D1+D2 (D1D2MO) and knockdown of D3 (D3MO) both resulted in transcriptional regulation of metabolism and (muscle) development in abdomen and tail, together with reduced growth, impaired swim bladder inflation, reduced protein content and reduced motility. The reduced growth and impaired swim bladder inflation in D1D2MO could be due to lower levels of T3 which is known to drive growth and development. The pronounced upregulation of a large number of transcripts coding for key proteins in ATP-producing pathways in D1D2MO could reflect a compensatory response to a decreased metabolic rate, also typically linked to hypothyroidy. Compared to D1D2MO, the effects were more pronounced or more frequent in D3MO, in which hyperthyroidy is expected. More specifically, increased heart rate, delayed hatching and increased carbohydrate content were observed only in D3MO. An increase of the metabolic rate, a decrease of the metabolic efficiency and a stimulation of gluconeogenesis using amino acids as substrates may have been involved in the observed reduced protein content, growth and motility in D3MO larvae. Furthermore, expression of transcripts involved in eye development and phototransduction was decreased in both knockdown conditions, suggesting that both may impair eye development and function. This study provides new insights, not only into the role of deiodinases, but also into the importance of a correct TH balance during vertebrate embryonic development. A-optimal design. Experimental design, D1D2MO vs SCMO and D3MO vs SCMO. Biological replicates: 4 SCMO, 4 D1D2MO, 4 D3MO

Project description:The role of deiodinase-mediated TH effects in early vertebrate development is only partially understood. Therefore, we investigated the role of deiodinases during early development of zebrafish until 96 hours post fertilization at the level of the transcriptome, biochemistry, morphology and physiology using morpholino (MO) knockdown. Knockdown of D1+D2 (D1D2MO) and knockdown of D3 (D3MO) both resulted in transcriptional regulation of metabolism and (muscle) development in abdomen and tail, together with reduced growth, impaired swim bladder inflation, reduced protein content and reduced motility. The reduced growth and impaired swim bladder inflation in D1D2MO could be due to lower levels of T3 which is known to drive growth and development. The pronounced upregulation of a large number of transcripts coding for key proteins in ATP-producing pathways in D1D2MO could reflect a compensatory response to a decreased metabolic rate, also typically linked to hypothyroidy. Compared to D1D2MO, the effects were more pronounced or more frequent in D3MO, in which hyperthyroidy is expected. More specifically, increased heart rate, delayed hatching and increased carbohydrate content were observed only in D3MO. An increase of the metabolic rate, a decrease of the metabolic efficiency and a stimulation of gluconeogenesis using amino acids as substrates may have been involved in the observed reduced protein content, growth and motility in D3MO larvae. Furthermore, expression of transcripts involved in eye development and phototransduction was decreased in both knockdown conditions, suggesting that both may impair eye development and function. This study provides new insights, not only into the role of deiodinases, but also into the importance of a correct TH balance during vertebrate embryonic development. A-optimal design. Experimental design, D1D2MO vs SCMO and D3MO vs SCMO. Biological replicates: 4 SCMO, 4 D1D2MO, 4 D3MO

Project description:An imbalance in thyroid hormones (THs) is associated with reversible dementia and Alzheimer’s disease (AD) pathogenesis. Whether hypothyroidism occurs in AD brains and how it affects AD pathology remain largely unknown. Here, we find that reduced conversion of thyroxine (T4) to tri-iodothyronine (T3) in the brain by decreased iodothyronine deiodinase 2 (DIO2) leads to hippocampal hypothyroidism in early AD model mice prior to TH changes in the blood. A TH deficiency causes immune tolerance with decreased phagocytic activity in microglia, thereby aggravating AD pathology. We demonstrate that microglial ecto-5’-nucleotidase (CD73) is reduced in the hypothyroid state and that its inhibition contributes to immune tolerance in microglia. Thus, our data define a molecular mechanism through which decreased conversion of T4 to T3 in the early AD brain, and consequent brain hypothyroidism causes microglial dysfunction and exacerbates AD pathology.

Project description:An imbalance in thyroid hormones (THs) is associated with reversible dementia and Alzheimer’s disease (AD) pathogenesis. Whether hypothyroidism occurs in AD brains and how it affects AD pathology remain largely unknown. Here, we find that reduced conversion of thyroxine (T4) to tri-iodothyronine (T3) in the brain by decreased iodothyronine deiodinase 2 (DIO2) leads to hippocampal hypothyroidism in early AD model mice prior to TH changes in the blood. A TH deficiency causes immune tolerance with decreased phagocytic activity in microglia, thereby aggravating AD pathology. We demonstrate that microglial ecto-5’-nucleotidase (CD73) is reduced in the hypothyroid state and that its inhibition contributes to immune tolerance in microglia. Thus, our data define a molecular mechanism through which decreased conversion of T4 to T3 in the early AD brain, and consequent brain hypothyroidism causes microglial dysfunction and exacerbates AD pathology.

Project description:The role of deiodinase-mediated TH effects in early vertebrate development is only partially understood. Therefore, we investigated the role of deiodinases during early development of zebrafish until 96 hours post fertilization at the level of the transcriptome, biochemistry, morphology and physiology using morpholino (MO) knockdown. Knockdown of D1+D2 (D1D2MO) and knockdown of D3 (D3MO) both resulted in transcriptional regulation of metabolism and (muscle) development in abdomen and tail, together with reduced growth, impaired swim bladder inflation, reduced protein content and reduced motility. The reduced growth and impaired swim bladder inflation in D1D2MO could be due to lower levels of T3 which is known to drive growth and development. The pronounced upregulation of a large number of transcripts coding for key proteins in ATP-producing pathways in D1D2MO could reflect a compensatory response to a decreased metabolic rate, also typically linked to hypothyroidy. Compared to D1D2MO, the effects were more pronounced or more frequent in D3MO, in which hyperthyroidy is expected. More specifically, increased heart rate, delayed hatching and increased carbohydrate content were observed only in D3MO. An increase of the metabolic rate, a decrease of the metabolic efficiency and a stimulation of gluconeogenesis using amino acids as substrates may have been involved in the observed reduced protein content, growth and motility in D3MO larvae. Furthermore, expression of transcripts involved in eye development and phototransduction was decreased in both knockdown conditions, suggesting that both may impair eye development and function. This study provides new insights, not only into the role of deiodinases, but also into the importance of a correct TH balance during vertebrate embryonic development.

Project description:The role of deiodinase-mediated TH effects in early vertebrate development is only partially understood. Therefore, we investigated the role of deiodinases during early development of zebrafish until 96 hours post fertilization at the level of the transcriptome, biochemistry, morphology and physiology using morpholino (MO) knockdown. Knockdown of D1+D2 (D1D2MO) and knockdown of D3 (D3MO) both resulted in transcriptional regulation of metabolism and (muscle) development in abdomen and tail, together with reduced growth, impaired swim bladder inflation, reduced protein content and reduced motility. The reduced growth and impaired swim bladder inflation in D1D2MO could be due to lower levels of T3 which is known to drive growth and development. The pronounced upregulation of a large number of transcripts coding for key proteins in ATP-producing pathways in D1D2MO could reflect a compensatory response to a decreased metabolic rate, also typically linked to hypothyroidy. Compared to D1D2MO, the effects were more pronounced or more frequent in D3MO, in which hyperthyroidy is expected. More specifically, increased heart rate, delayed hatching and increased carbohydrate content were observed only in D3MO. An increase of the metabolic rate, a decrease of the metabolic efficiency and a stimulation of gluconeogenesis using amino acids as substrates may have been involved in the observed reduced protein content, growth and motility in D3MO larvae. Furthermore, expression of transcripts involved in eye development and phototransduction was decreased in both knockdown conditions, suggesting that both may impair eye development and function. This study provides new insights, not only into the role of deiodinases, but also into the importance of a correct TH balance during vertebrate embryonic development.