Takasawa Kei, Ono Makoto, Hijikata Atsushi, Matsubara Yohei, Katsumata Noriyuki, Takagi Masatoshi, Morio Tomohiro, Ohara Osamu, Kashimada Kenichi, Mizutani Shuki
Department of Pediatrics and Developmental Biology, Tokyo Medical and Dental University, Tokyo, Japan.
Clin Endocrinol (Oxf). 2014 Jun;80(6):782-9. doi: 10.1111/cen.12394. Epub 2014 Jan 16.
Classical 3β-hydroxysteroid dehydrogenase (3β-HSD) deficiency (3β-HSDD) is caused by loss-of-function mutations in the HSD3B2 gene encoding type II 3β-HSD, which has a key role in steroid biosynthesis, converting Δ5-steroids to Δ4-steroids in adrenal glands and gonads.
A patient (46, XX) was found to have elevated 17-hydroxyprogesterone (17-OHP) [203 nmol/l (normal range: 2·94 ± 0·9 nmol/l)] by newborn screening. Endocrinological examination revealed dramatically increased Δ5-steroids [e.g. 17-OH pregnenolone: 910 nmol/l (normal range: 12·6 ± 10·5 nmol/l)]. The patient had virilization of external genitalia with labial fusion, suggesting classical 3β-HSDD.
Consistent with the endocrinological data, the patient was a compound heterozygote for two novel missense mutations (p.Y190C and p.S218P) that were identified in HSD3B2. Both Y190 and S218 are conserved among mammals. The mutant proteins had severely impaired residual enzymatic activity in vitro, although both mutants retained higher activity for 17-OH pregnenolone than for the other Δ5-steroids. In a three-dimensional model of the enzyme based on the known structures of similar proteins, both mutations were located extremely close to the predicted substrate-binding pocket. This suggests that the mutations can cause a local conformational change in the substrate-binding pocket, leading to alterations of the binding affinities for Δ5-steroids.
We identified two novel missense mutations of HSD3B2 that resulted in unbalanced residual enzymatic activities for Δ5-steroids. As a potential novel mechanism, we propose that the mutations, which differently affect the activity towards different substrates, the effects of these mutations provide novel insights into the pathophysiology of 3β-HSDD.
经典3β-羟基类固醇脱氢酶(3β-HSD)缺乏症(3β-HSDD)是由编码II型3β-HSD的HSD3B2基因功能丧失性突变引起的,该酶在类固醇生物合成中起关键作用,可将肾上腺和性腺中的Δ5-类固醇转化为Δ4-类固醇。
一名46岁XX女性患者通过新生儿筛查发现17-羟孕酮(17-OHP)升高[203 nmol/L(正常范围:2.94±0.9 nmol/L)]。内分泌检查显示Δ5-类固醇显著增加[例如17-羟孕烯醇酮:910 nmol/L(正常范围:12.6±10.5 nmol/L)]。患者出现外生殖器男性化伴阴唇融合,提示经典3β-HSDD。
与内分泌数据一致,该患者是HSD3B2中两个新的错义突变(p.Y190C和p.S218P)的复合杂合子。Y190和S218在哺乳动物中均保守。突变蛋白在体外的残余酶活性严重受损,尽管两个突变体对17-羟孕烯醇酮的活性均高于对其他Δ5-类固醇的活性。在基于相似蛋白质已知结构的酶三维模型中,两个突变均位于极其靠近预测的底物结合口袋处。这表明这些突变可导致底物结合口袋发生局部构象变化,从而导致对Δ5-类固醇的结合亲和力改变。
我们鉴定出HSD3B2的两个新错义突变,其导致对Δ5-类固醇的残余酶活性失衡。作为一种潜在的新机制,我们提出这些对不同底物活性影响不同的突变,为3β-HSDD的病理生理学提供了新见解。
