Tsachaki Maria, Meyer Arne, Weger Benjamin, Kratschmar Denise V, Tokarz Janina, Adamski Jerzy, Belting Heinz-Georg, Affolter Markus, Dickmeis Thomas, Odermatt Alex
Division of Molecular and Systems ToxicologyDepartment of Pharmaceutical Sciences, University of Basel, Basel, Switzerland.
AstraZeneca AGZug, Switzerland.
J Endocrinol. 2017 Feb;232(2):323-335. doi: 10.1530/JOE-16-0495. Epub 2016 Dec 7.
Zebrafish are widely used as model organism. Their suitability for endocrine studies, drug screening and toxicity assessements depends on the extent of conservation of specific genes and biochemical pathways between zebrafish and human. Glucocorticoids consist of inactive 11-keto (cortisone and 11-dehydrocorticosterone) and active 11β-hydroxyl forms (cortisol and corticosterone). In mammals, two 11β-hydroxysteroid dehydrogenases (11β-HSD1 and 11β-HSD2) interconvert active and inactive glucocorticoids, allowing tissue-specific regulation of glucocorticoid action. Furthermore, 11β-HSDs are involved in the metabolism of 11-oxy androgens. As zebrafish and other teleost fish lack a direct homologue of 11β-HSD1, we investigated whether they can reduce 11-ketosteroids. We compared glucocorticoid and androgen metabolism between human and zebrafish using recombinant enzymes, microsomal preparations and zebrafish larvae. Our results provide strong evidence for the absence of 11-ketosteroid reduction in zebrafish. Neither human 11β-HSD3 nor the two zebrafish 11β-HSD3 homologues, previously hypothesized to reduce 11-ketosteroids, converted cortisone and 11-ketotestosterone (11KT) to their 11β-hydroxyl forms. Furthermore, zebrafish microsomes were unable to reduce 11-ketosteroids, and exposure of larvae to cortisone or the synthetic analogue prednisone did not affect glucocorticoid-dependent gene expression. Additionally, a dual-role of 11β-HSD2 by inactivating glucocorticoids and generating the main fish androgen 11KT was supported. Thus, due to the lack of 11-ketosteroid reduction, zebrafish and other teleost fish exhibit a limited tissue-specific regulation of glucocorticoid action, and their androgen production pathway is characterized by sustained 11KT production. These findings are of particular significance when using zebrafish as a model to study endocrine functions, stress responses and effects of pharmaceuticals.
斑马鱼被广泛用作模式生物。它们适用于内分泌研究、药物筛选和毒性评估,这取决于斑马鱼与人类之间特定基因和生化途径的保守程度。糖皮质激素由无活性的11-酮形式(可的松和11-脱氢皮质酮)和有活性的11β-羟基形式(皮质醇和皮质酮)组成。在哺乳动物中,两种11β-羟基类固醇脱氢酶(11β-HSD1和11β-HSD2)可使活性和无活性的糖皮质激素相互转化,从而实现糖皮质激素作用的组织特异性调节。此外,11β-HSDs还参与11-氧代雄激素的代谢。由于斑马鱼和其他硬骨鱼缺乏11β-HSD1的直接同源物,我们研究了它们是否能够还原11-酮类固醇。我们使用重组酶、微粒体制剂和斑马鱼幼虫比较了人类和斑马鱼之间的糖皮质激素和雄激素代谢。我们的结果为斑马鱼中不存在11-酮类固醇还原提供了有力证据。先前推测可还原11-酮类固醇的人类11β-HSD3以及两种斑马鱼11β-HSD3同源物,均未将可的松和11-酮睾酮(11KT)转化为它们的11β-羟基形式。此外,斑马鱼微粒体无法还原11-酮类固醇,并且将幼虫暴露于可的松或合成类似物泼尼松并不影响糖皮质激素依赖性基因表达。此外,还支持了11β-HSD2通过使糖皮质激素失活并生成主要的鱼类雄激素11KT而发挥的双重作用。因此,由于缺乏11-酮类固醇还原,斑马鱼和其他硬骨鱼对糖皮质激素作用的组织特异性调节有限,并且它们的雄激素产生途径的特点是持续产生11KT。当使用斑马鱼作为模型来研究内分泌功能、应激反应和药物作用时,这些发现具有特别重要的意义。
