Elevated thyroid manganese reduces thyroid iodine to induce hypothyroidism in mice, but not rats, lacking SLC30A10 transporter.

IF 2.9 3区 生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY
Metallomics Pub Date : 2024-07-01 DOI:10.1093/mtomcs/mfae029
Steven Hutchens, Ashvini Melkote, Thomas Jursa, William Shawlot, Leonardo Trasande, Donald R Smith, Somshuvra Mukhopadhyay
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Abstract

Elevated manganese (Mn) accumulates in the brain and induces neurotoxicity. SLC30A10 is an Mn efflux transporter that controls body Mn levels. We previously reported that full-body Slc30a10 knockout mice (1) recapitulate the body Mn retention phenotype of humans with loss-of-function SLC30A10 mutations and (2) unexpectedly develop hypothyroidism induced by Mn accumulation in the thyroid, which reduces intra-thyroid thyroxine. Subsequent analyses of National Health and Nutrition Examination Survey data identified an association between serum Mn and subclinical thyroid changes. The emergence of thyroid deficits as a feature of Mn toxicity suggests that changes in thyroid function may be an underappreciated, but critical, modulator of Mn-induced disease. To better understand the relationship between thyroid function and Mn toxicity, here we further defined the mechanism of Mn-induced hypothyroidism using mouse and rat models. Slc30a10 knockout mice exhibited a profound deficit in thyroid iodine levels that occurred contemporaneously with increases in thyroid Mn levels and preceded the onset of overt hypothyroidism. Wild-type Mn-exposed mice also exhibited increased thyroid Mn levels, an inverse correlation between thyroid Mn and iodine levels, and subclinical hypothyroidism. In contrast, thyroid iodine levels were unaltered in newly generated Slc30a10 knockout rats despite an increase in thyroid Mn levels, and the knockout rats were euthyroid. Thus, Mn-induced thyroid dysfunction in genetic or Mn exposure-induced mouse models occurs due to a reduction in thyroid iodine subsequent to an increase in thyroid Mn levels. Moreover, rat and mouse thyroids have differential sensitivities to Mn, which may impact the manifestations of Mn-induced disease in these routinely used animal models.

在缺乏 SLC30A10 转运体的小鼠(而非大鼠)体内,甲状腺锰升高会减少甲状腺碘,从而诱发甲状腺功能减退症。
锰(Mn)升高会在大脑中蓄积并诱发神经中毒。SLC30A10 是一种锰外排转运体,可控制体内的锰含量。我们以前曾报道过全身 Slc30a10 基因敲除小鼠:(1)再现了功能缺失 SLC30A10 基因突变的人类体内锰潴留的表型;(2)出乎意料的是,由于甲状腺中的锰蓄积导致甲状腺内甲状腺素减少,从而诱发甲状腺功能减退症。随后对全国健康与营养调查数据的分析发现,血清锰与亚临床甲状腺变化之间存在关联。甲状腺功能缺陷是锰毒性的一个特征,这表明甲状腺功能的变化可能是锰诱发疾病的一个未被重视但却至关重要的调节因素。为了更好地理解甲状腺功能与锰毒性之间的关系,我们在此利用小鼠和大鼠模型进一步明确了锰诱导甲状腺功能减退的机制。Slc30a10 基因敲除小鼠的甲状腺碘水平严重不足,这种情况与甲状腺锰的增加同时发生,并先于明显的甲状腺功能减退症出现。暴露于锰的野生型小鼠也表现出甲状腺锰水平升高、甲状腺锰和碘水平呈反相关以及亚临床甲状腺机能减退。与此相反,尽管甲状腺锰含量增加,但新产生的 Slc30a10 基因敲除大鼠的甲状腺碘水平没有发生变化,而且基因敲除大鼠是甲状腺功能正常的。因此,在遗传或锰暴露诱导的小鼠模型中,锰诱导的甲状腺功能障碍是由于甲状腺锰增加后甲状腺碘减少所致。此外,大鼠和小鼠甲状腺对锰的敏感性不同,这可能会影响锰诱导的疾病在这些常规使用的动物模型中的表现。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Metallomics
Metallomics 生物-生化与分子生物学
CiteScore
7.00
自引率
5.90%
发文量
87
审稿时长
1 months
期刊介绍: Global approaches to metals in the biosciences
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