Mébarki F, Sanchez R, Rhéaume E, Laflamme N, Simard J, Forest M G, Bey-Omar F, David M, Labrie F, Morel Y
INSERM U-329, Université de Lyon, France.
J Clin Endocrinol Metab. 1995 Jul;80(7):2127-34. doi: 10.1210/jcem.80.7.7608265.
Recently, the structure of two genes encoding isoenzymes responsible for 3 beta-hydroxysteroid dehydrogenase/delta 5-delta 4-isomerase (3 beta HSD) activity in the human was elucidated. This activity is an essential step in the biosynthesis of all classes of steroid hormones. In the classic severe form of 3 beta HSD deficiency, patients present with adrenal insufficiency, various degrees of salt loss, and incomplete masculinization in males. Here we report the characterization of the molecular basis of congenital adrenal hyperplasia due to 3 beta HSD deficiency in a male pseudohermaphrodite born from consanguineous parents and having no clinical salt loss. To analyze the structure of the type I and II 3 beta HSD genes of the patient, DNA fragments, generated by polymerase chain reaction amplification of the four exons and the exon-intron boundaries of these genes, were directly sequenced. The patients carried a homozygous missense mutation converting Asn100 to Ser in exon 3 of his type II 3 beta HSD gene. His parents were heterozygous for the same point mutation. The absence of clinical salt loss associated with a male pseudohermaphroditism suggested that 3 beta HSD activity was impaired to different levels in the testes and adrenal. To elucidate whether this N100S missense mutation affected preferentially a steroidogenic pathway, enzymatic activity was analyzed by in vitro analysis of mutant recombinant enzyme generated by site-directed mutagenesis after its transient expression in COS-1 cells. Using homogenates from transfected cells, the N100S 3 beta HSD enzyme showed a Km value for pregnenolone of 25 +/- 3 mumol/L compared with 3.5 +/- 0.2 mumol/L for the normal human type II 3 beta HSD enzyme. Similar results were obtained using dehydroepiandrosterone as substrate. In addition to decreasing apparent affinity, the N100S mutation decreased the relative specific activity (Vmax), leading to a relative specificity (relative Vmax/Km) 2.7% and 11% that of normal type II 3 beta HSD using pregnenolone or dehydroepiandrosterone as substrate, respectively. Moreover, the mutant N100S protein had an apparent decreased affinity for NAD+, with a Km value of 650 +/- 66 mumol/L compared with 20 +/- 2 mumol/L for normal type II 3 beta HSD. Except for the hypothetical effect of local factors, these findings suggest that a very weak residual activity of the normal type II 3 beta HSD enzyme could prevent salt loss, but it was insufficient for normal male sex differentiation.(ABSTRACT TRUNCATED AT 400 WORDS)
最近,编码负责人类3β-羟基类固醇脱氢酶/δ5-δ4-异构酶(3βHSD)活性的同工酶的两个基因的结构得以阐明。该活性是所有类固醇激素生物合成中的关键步骤。在经典的严重型3βHSD缺乏症中,患者表现为肾上腺功能不全、不同程度的失盐以及男性患者的不完全男性化。在此,我们报告了一名男性假两性畸形患者先天性肾上腺增生的分子基础特征,该患者父母近亲结婚,无临床失盐症状。为分析该患者I型和II型3βHSD基因的结构,通过聚合酶链反应扩增这些基因的四个外显子及外显子-内含子边界产生的DNA片段被直接测序。该患者II型3βHSD基因的外显子3存在一个纯合错义突变,将Asn100转变为Ser。其父母为该同一位点突变的杂合子。男性假两性畸形却无临床失盐症状表明,3βHSD活性在睾丸和肾上腺中受到不同程度的损害。为阐明该N100S错义突变是否优先影响类固醇生成途径,在COS-1细胞中瞬时表达后,通过定点诱变产生的突变重组酶的体外分析来检测酶活性。使用转染细胞的匀浆,N100S 3βHSD酶对孕烯醇酮的Km值为25±3μmol/L,而正常人类II型3βHSD酶为3.5±0.2μmol/L。以脱氢表雄酮为底物时也得到类似结果。除降低表观亲和力外,N100S突变还降低了相对比活性(Vmax),以孕烯醇酮或脱氢表雄酮为底物时,其相对特异性(相对Vmax/Km)分别为正常II型3βHSD的2.7%和11%。此外,突变的N100S蛋白对NAD+的表观亲和力降低,Km值为650±66μmol/L,而正常II型3βHSD为20±2μmol/L。除局部因素的假设影响外,这些发现表明正常II型3βHSD酶非常微弱的残余活性可防止失盐,但不足以实现正常的男性性别分化。(摘要截短于400字)
