Kristof Rada scite author profile

Kristof Rada

4Publications

3Citation Statements Received

234Citation Statements Given

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Affiliations

Czech Academy of Sciences, Institute of Experimental Medicine, Institute of Experimental Medicine

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Axonal T3 uptake and transport can trigger thyroid hormone signaling in the brain

Salas-Lucia

Fekete

Sinkó

et al. 2023

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The development of the brain, as well as mood and cognitive functions, are affected by thyroid hormone (TH) signaling. Neurons are the critical cellular target for TH action, with T3 regulating the expression of important neuronal gene sets. However, the steps involved in T3 signaling remain poorly known given that neurons express high levels of type 3 deiodinase (D3), which inactivates both T4 and T3. To investigate this mechanism, we used a compartmentalized microfluid device and identified a novel neuronal pathway of T3 transport and action that involves axonal T3 uptake into clathrin-dependent, endosomal/non-degradative lysosomes (NDLs). NDLs-containing T3 are retrogradely transported via microtubules, delivering T3 to the cell nucleus, and doubling the expression of a T3-responsive reporter gene. The NDLs also contain the monocarboxylate transporter 8 (Mct8) and D3, which transport and inactivate T3, respectively. Notwithstanding, T3 gets away from degradation because D3's active center is in the cytosol. Moreover, we used a unique mouse system to show that T3 implanted in specific brain areas can trigger selective signaling in distant locations, as far as the contralateral hemisphere. These findings provide a pathway for L-T3 to reach neurons and resolve the paradox of T3 signaling in the brain amid high D3 activity.

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A Pathway for T3 Signaling in the Brain to Improve the Variable Effectiveness of Therapy With L-T4

Salas-Lucia

Fekete

Sinkó

et al. 2022

Preprint

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The effectiveness of therapy for hypothyroidism with levothyroxine (L-T4) depends on patient's ability to activate T4 to T3; altered in carriers of a common deiodinase polymorphism (Thr92Ala-DIO2). Some patients that exhibit impaired mood and cognition improve with liothyronine (L-T3), but the underlying mechanisms remain unknown. Here we show that the T3-indicator mouse carrying the Thr92Ala-DIO2 polymorphism exhibits a hippocampal-specific reduction in T3 activation and signaling that limits the effectiveness of L-T4 therapy. To understand the L-T3 effect, we used a compartmentalized microfluid device and identified a novel neuronal pathway of T3 transport and action that involves axonal T3 uptake into clathrin-dependent, endosomal/non-degradative lysosomes (NDLs). NDLs-containing T3 are retrogradely transported via microtubules, delivering relatively large amounts of T3 to the cell nucleus, doubling the expression of the T3-responsive reporter gene. The NDLs also contain the monocarboxylate transporter 8 (Mct8) and the type 3 deiodinase (Dio3), which transports and inactivates T3, respectively. Notwithstanding, T3 gets away from degradation because D3 active center is in the cytosol. These findings provide (i) a basis for the variable effectiveness of L-T4 therapy, (ii) a pathway for L-T3 to reach neurons, and (iii) resolve the paradox of T3 signaling in the brain amid high D3 activity.

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Tetrabromobisphenol A and Diclazuril Evoke Tissue-Specific Changes of Thyroid Hormone Signaling in Male Thyroid Hormone Action Indicator Mice

Sinkó

Rada

Kollár

et al. 2022

IJMS

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Thyroid hormone (TH) signaling is a prerequisite of normal tissue function. Environmental pollutants with the potential to disrupt endocrine functions represent an emerging threat to human health and agricultural production. We used our Thyroid Hormone Action Indicator (THAI) mouse model to study the effects of tetrabromobisphenol A (TBBPA; 150 mg/bwkg/day orally for 6 days) and diclazuril (10.0 mg/bwkg/day orally for 5 days), a known and a potential hormone disruptor, respectively, on local TH economy. Tissue-specific changes of TH action were assessed in 90-day-old THAI mice by measuring the expression of a TH-responsive luciferase reporter in tissue samples and by in vivo imaging (14-day-long treatment accompanied with imaging on day 7, 14 and 21 from the first day of treatment) in live THAI mice. This was followed by promoter assays to elucidate the mechanism of the observed effects. TBBPA and diclazuril impacted TH action differently and tissue-specifically. TBBPA disrupted TH signaling in the bone and small intestine and impaired the global TH economy by decreasing the circulating free T4 levels. In the promoter assays, TBBPA showed a direct stimulatory effect on the hdio3 promoter, indicating a potential mechanism for silencing TH action. In contrast, diclazuril acted as a stimulator of TH action in the liver, skeletal muscle and brown adipose tissue without affecting the Hypothalamo-Pituitary-Thyroid axis. Our data demonstrate distinct and tissue-specific effects of TBBPA and diclazuril on local TH action and prove that the THAI mouse is a novel mammalian model to identify TH disruptors and their tissue-specific effects.

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Author response: Axonal T3 uptake and transport can trigger thyroid hormone signaling in the brain

Salas-Lucia

Fekete

Sinkó

et al. 2023

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Kristof Rada

Axonal T3 uptake and transport can trigger thyroid hormone signaling in the brain

A Pathway for T3 Signaling in the Brain to Improve the Variable Effectiveness of Therapy With L-T4

Tetrabromobisphenol A and Diclazuril Evoke Tissue-Specific Changes of Thyroid Hormone Signaling in Male Thyroid Hormone Action Indicator Mice

Author response: Axonal T3 uptake and transport can trigger thyroid hormone signaling in the brain

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