Inhibition of Thyroid Hormone Signaling in the Zona Incerta Alters Basal Metabolic Rate, Behavior, and Serum Glucocorticoids in Male Mice.

IF 5.8 1区 医学 Q1 ENDOCRINOLOGY & METABOLISM
Thyroid Pub Date : 2024-10-01 Epub Date: 2024-09-13 DOI:10.1089/thy.2024.0209
Julia Maier, Riccardo Dore, Rebecca Oelkrug, Annika Glatzel, Anna-Lena Cremer, Sonja Binder, Markus Schwaninger, Henrik Oster, Heiko Backes, Jens Mittag
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Abstract

Background: It has long been known that thyroid disease can lead to changes in energy metabolism, thermoregulation, and anxiety behavior. While these actions have been partially attributed to thyroid hormone (TH) receptor α1 (TRα1) action in the brain, the precise neuroanatomical substrates have remain elusive. Methods: We used PET-CT scans to identify brain regions affected by TH. We then inhibited TRα1 signaling specifically in the most affected region, the zona incerta (ZI), a still mysterious region previously implicated in thermogenesis and anxiety. To this end, we used an adeno-associated virus (AAV) expressing a dominant-negative TRα1R384C in wild-type mice and phenotyped the animals. Finally, we used tyrosine hydroxylase-Cre mice to test specifically the contribution of ZI dopaminergic neurons. Results: Our data showed that AAV-mediated inhibition of TRα1 signaling in the ZI lead to increased energy expenditure at thermoneutrality, while body temperature regulation remained unaffected. Moreover, circulating glucocorticoid levels were increased, and a mild habituation problem was observed in the open field test. No effects were observed when TRα1 signaling was selectively inhibited in dopaminergic neurons. Conclusions: Our findings suggest that altered TH signaling in the ZI is not involved in body temperature regulation but can affect basal metabolism and modulates stress responses.

抑制突起区甲状腺激素信号改变雄性小鼠的基础代谢率、行为和血清糖皮质激素
背景:众所周知,甲状腺疾病可导致能量代谢、体温调节和焦虑行为的改变。虽然这些作用部分归因于甲状腺激素受体α1(TRα1)在大脑中的作用,但精确的神经解剖基质仍然难以捉摸:方法:我们利用PET-CT扫描确定了受甲状腺激素影响的脑区。方法:我们利用 PET-CT 扫描确定了受甲状腺激素影响的脑区,然后特异性地抑制了受影响最严重区域的 TRα1 信号传导。为此,我们在野生型小鼠体内使用了表达显性阴性 TRα1R384C 的腺相关病毒(AAV),并对动物进行了表型分析。最后,我们使用酪氨酸羟化酶-Cre小鼠专门检测了插入带多巴胺能神经元的贡献:结果:我们的数据显示,AAV介导的对内侧透明带TRα1信号传导的抑制导致热中性能量消耗增加,而体温调节不受影响。此外,循环中的糖皮质激素水平升高,在开阔地试验中观察到轻微的习惯性问题。当选择性抑制多巴胺能神经元中的TRα1信号传导时,未观察到任何影响:我们的研究结果表明,入球带甲状腺激素信号的改变并不参与体温调节,但会影响基础代谢并调节应激反应。
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来源期刊
Thyroid
Thyroid 医学-内分泌学与代谢
CiteScore
12.30
自引率
6.10%
发文量
195
审稿时长
6 months
期刊介绍: This authoritative journal program, including the monthly flagship journal Thyroid, Clinical Thyroidology® (monthly), and VideoEndocrinology™ (quarterly), delivers in-depth coverage on topics from clinical application and primary care, to the latest advances in diagnostic imaging and surgical techniques and technologies, designed to optimize patient care and outcomes. Thyroid is the leading, peer-reviewed resource for original articles, patient-focused reports, and translational research on thyroid cancer and all thyroid related diseases. The Journal delivers the latest findings on topics from primary care to clinical application, and is the exclusive source for the authoritative and updated American Thyroid Association (ATA) Guidelines for Managing Thyroid Disease.
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